Synchronization signal carrying method and user equipment

ABSTRACT

Embodiments of the present invention provide a synchronization signal carrying method and an apparatus. The synchronization signal carrying method in the present invention includes: determining, by first user equipment, a priority parameter of a synchronization signal; determining, by the first user equipment according to the priority parameter, a resource for carrying the synchronization signal, where a configuration of the resource indicates the priority parameter; and sending, by the first user equipment, the synchronization signal to second user equipment by using the resource, so that the second user equipment determines a synchronization signal for the second user equipment. The embodiments of the present invention enable a more flexible synchronization signal determining manner in a D2D communications system.

TECHNICAL FIELD

Embodiments of the present invention relate to the field ofcommunications technologies, and in particular, to a synchronizationsignal carrying method and user equipment.

BACKGROUND

The device-to-device proximity service (Device to Device ProximityService, D2D ProSe for short) has become a research topic of the LongTerm Evolution (Long Term Evolution, LTE) system Rel.12 of the 3rdGeneration Partnership Project (3rd Generation Partnership Project, 3GPPfor short). The D2D Prose provided by using an LTE physical layer cannot only expand a service scope of the LTE system but also enable theD2D Prose to be used by more users. The ProSe includes D2D discovery andD2D communication. D2D discovery refers to that user equipment with D2Dfunction discovers a signal and learns of existence of anther userequipment, and D2D communication refers to direct communication betweendevices with D2D functions. Time synchronization (including framesynchronization, bit synchronization, sampling point synchronization,and the like) and frequency synchronization of the system are two majorissues during design of D2D communication. Only after obtaining precisesynchronization can a receiving device ensure that subsequentcommunication functions such as channel estimation, demodulation, anddecoding work properly.

In the prior art, synchronization of a D2D communications system is asfollows: A transmit end sends a synchronization sequence, and a receiveend acquires system synchronization by performing a time synchronizationalgorithm and a frequency synchronization algorithm on thesynchronization sequence. When the transmit end sends thesynchronization sequence, a time reference source is required forcalibrating a synchronization signal sent by the transmit end.Synchronization precision of different time reference sources isdifferent, which leads to different precision of synchronization signalssent by the transmit end. As a receiver, user equipment usuallydetermines a synchronization signal according to strength of thesynchronization signal. This determining manner is relatively monotonousand lacks flexibility.

SUMMARY

Embodiments of the present invention provide a synchronization signalcarrying method and user equipment, so as to improve flexibility of asynchronization signal determining manner during D2D communication.

According to a first aspect, an embodiment of the present inventionprovides a synchronization signal carrying method, including:

determining, by first user equipment, a priority parameter of asynchronization signal;

determining, by the first user equipment according to the priorityparameter, a resource for carrying the synchronization signal, where aconfiguration of the resource indicates the priority parameter; and

sending, by the first user equipment, the synchronization signal tosecond user equipment by using the resource, so that the second userequipment determines a synchronization signal for the second userequipment.

In a first implementation manner of the first aspect, the determining,by the first user equipment according to the priority parameter, aresource for carrying the synchronization signal specifically includes:

determining, by the first user equipment, different resources to carrysynchronization signals with different priority parameters.

With reference to the first implementation manner of the first aspect,in a second implementation manner, the first user equipment determinesdifferent resources to carry synchronization signals with differentpriority parameters.

With reference to the first aspect, the first implementation manner, andthe second implementation manner, in a third implementation manner, thepriority parameter includes at least one of a level and a layer, wherethe level is used to identify a source of the synchronization signal orused to identify precision of the synchronization signal; and the layeris used to identify a forwarding level of the synchronization signal;and the synchronization signals with different priority parameters arespecifically synchronization signals that differ in at least one of thelevel and the layer.

With reference to the first aspect, the first implementation manner, thesecond implementation manner, and the third implementation manner, in afourth implementation manner, the source of the synchronization signalincludes: a global satellite positioning system, a network device, orthe first user equipment.

With reference to the first aspect, the first implementation manner, thesecond implementation manner, the third implementation manner, and thefourth implementation manner, in a fifth implementation manner, theresource includes: a time domain resource, a frequency domain resource,and a codeword resource; and the different resources are specificallyresources that differ in at least one of a time domain, a frequencydomain, and a codeword.

With reference to the first aspect, the first implementation manner, thesecond implementation manner, the third implementation manner, thefourth implementation manner, and the fifth implementation manner, in asixth implementation manner, that time domain resources carrying thesynchronization signals are different includes at least one of thefollowing: serial numbers of data frames carrying the synchronizationsignals are different; serial numbers of timeslots carrying thesynchronization signals are different; serial numbers of subframescarrying the synchronization signals are different; and serial numbersof OFDM symbols carrying the synchronization signals are different.

With reference to the first aspect, the first implementation manner, thesecond implementation manner, the third implementation manner, thefourth implementation manner, the fifth implementation manner, and thesixth implementation manner, in a seventh implementation manner, thatfrequency domain resources carrying the synchronization signals aredifferent includes at least one of the following: serial numbers of PRBscarrying the synchronization signals are different; serial numbers ofsubcarriers carrying the synchronization signals are different; andserial numbers of subcarriers in a subcarrier group carrying thesynchronization signals are different.

With reference to the first aspect, the first implementation manner, thesecond implementation manner, the third implementation manner, thefourth implementation manner, the fifth implementation manner, the sixthimplementation manner, and the seventh implementation manner, in aneighth implementation manner, the resources that differ in a codewordare specifically resources that differ in a codeword sequence.

With reference to the first aspect, the first implementation manner, thesecond implementation manner, the third implementation manner, thefourth implementation manner, the fifth implementation manner, the sixthimplementation manner, the seventh implementation manner, and the eighthimplementation manner, in a ninth implementation manner, the codewordsequence is a sequence with a length of 63 bits:

${d_{u}(n)} = ^{{- j}\frac{\pi \; {{un}{({n + 1})}}}{63}}$n = 0, 1, …  , 30, 31, 32, …  , 61, 62,

where

a value of u is 25, 29, or 34, and three different codeword sequencesare generated separately.

According to a second aspect, an embodiment of the present inventionfurther provides a synchronization signal carrying method, including:

receiving, by second user equipment, a synchronization signal sent byfirst user equipment;

determining, by the second user equipment, a priority parameteraccording to a resource carrying the synchronization signal and acorrespondence between the resource and the priority parameter of thesynchronization signal; and

determining, by the second user equipment, a synchronization signal forthe second user equipment according to the priority parameter.

With reference to the second aspect, in a first implementation manner ofthe second aspect, synchronization signals with different priorityparameters are carried by using different resources.

With reference to the second aspect and the first implementation manner,in a second implementation manner, the priority parameter includes atleast one of a level and a layer, where the level is used to identify asource of the synchronization signal or used to identify precision ofthe synchronization signal; and the layer is used to identify aforwarding level of the synchronization signal; and the synchronizationsignals with different priority parameters are specificallysynchronization signals that differ in at least one of the level and thelayer.

With reference to the second aspect, the first implementation manner,and the second implementation manner, in a third implementation manner,the source of the synchronization signal includes: a global satellitepositioning system, a network device, or the first user equipment.

With reference to the second aspect, the first implementation manner,the second implementation manner, and the third implementation manner,in a fourth implementation manner, the resource includes: a time domainresource, a frequency domain resource, and a codeword resource; and thedifferent resources are specifically resources that differ in at leastone of a time domain, a frequency domain, and a codeword.

With reference to the first aspect, the first implementation manner, thesecond implementation manner, the third implementation manner, and thefourth implementation manner, in a fifth implementation manner, thattime domain resources carrying the synchronization signals are differentincludes at least one of the following: serial numbers of data framesare different; serial numbers of timeslots carrying the synchronizationsignals are different; serial numbers of subframes carrying thesynchronization signals are different; and serial numbers of OFDMsymbols carrying the synchronization signals are different.

With reference to the first aspect, the first implementation manner, thesecond implementation manner, the third implementation manner, thefourth implementation manner, and the fifth implementation manner, in asixth implementation manner, that frequency domain resources carryingthe synchronization signals are different includes at least one of thefollowing: serial numbers of PRBs carrying the synchronization signalsare different; serial numbers of subcarriers carrying thesynchronization signals are different; and serial numbers of subcarriersin a subcarrier group carrying the synchronization signals aredifferent.

With reference to the first aspect, the first implementation manner, thesecond implementation manner, the third implementation manner, thefourth implementation manner, the fifth implementation manner, and thesixth implementation manner, in a seventh implementation manner, theresources that differ in a codeword are specifically resources thatdiffer in a codeword sequence.

With reference to the first aspect, the first implementation manner, thesecond implementation manner, the third implementation manner, thefourth implementation manner, the fifth implementation manner, the sixthimplementation manner, and the seventh implementation manner, in aneighth implementation manner, the codeword sequence is a sequence with alength of 63 bits:

${d_{u}(n)} = ^{{- j}\frac{\pi \; {{un}{({n + 1})}}}{63}}$n = 0, 1, …  , 30, 31, 32, …  , 61, 62,

where

a value of u is 25, 29, or 34.

According to a third aspect, an embodiment of the present inventionfurther provides user equipment, including:

a parameter determining module, configured to determine a priorityparameter of a synchronization signal;

a resource determining module, configured to determine, according to thepriority parameter, a resource for carrying the synchronization signal,where a configuration of the resource indicates the priority parameter;and

a sending module, configured to send the synchronization signal tosecond user equipment by using the resource, so that the second userequipment determines a synchronization signal for the second userequipment.

In a first implementation manner of the third aspect, the resourcedetermining module is specifically configured to: determine differentresources to carry synchronization signals with different priorityparameters.

With reference to the first implementation manner of the third aspect,in a second implementation manner, the priority parameter includes atleast one of a level and a layer, where the level is used to identify asource of the synchronization signal or used to identify precision ofthe synchronization signal; and the layer is used to identify aforwarding level of the synchronization signal; and the synchronizationsignals with different priority parameters are specificallysynchronization signals that differ in at least one of the level and thelayer.

With reference to the third aspect, the first implementation manner, andthe second implementation manner, in a third implementation manner, thesource of the synchronization signal includes: a global satellitepositioning system, a network device, or the user equipment.

With reference to the third aspect, the first implementation manner, thesecond implementation manner, and the third implementation manner, in afourth implementation manner, the resource includes: a time domainresource, a frequency domain resource, and a codeword resource; and thedifferent resources are specifically resources that differ in at leastone of a time domain, a frequency domain, and a codeword.

With reference to the third aspect, the first implementation manner, thesecond implementation manner, the third implementation manner, and thefourth implementation manner, in a fifth implementation manner, thattime domain resources carrying the synchronization signals are differentincludes at least one of the following: serial numbers of data framescarrying the synchronization signals are different; serial numbers oftimeslots carrying the synchronization signals are different; serialnumbers of subframes carrying the synchronization signals are different;and serial numbers of OFDM symbols carrying the synchronization signalsare different.

With reference to the third aspect, the first implementation manner, thesecond implementation manner, the third implementation manner, thefourth implementation manner, and the fifth implementation manner, in asixth implementation manner, that frequency domain resources carryingthe synchronization signals are different includes at least one of thefollowing: serial numbers of PRBs carrying the synchronization signalsare different; serial numbers of subcarriers carrying thesynchronization signals are different; and serial numbers of subcarriersin a subcarrier group carrying the synchronization signals aredifferent.

With reference to the third aspect, the first implementation manner, thesecond implementation manner, the third implementation manner, thefourth implementation manner, the fifth implementation manner, and thesixth implementation manner, in a seventh implementation manner, theresources that differ in a codeword are specifically resources thatdiffer in a codeword sequence.

With reference to the third aspect, the first implementation manner, thesecond implementation manner, the third implementation manner, thefourth implementation manner, the fifth implementation manner, the sixthimplementation manner, and the seventh implementation manner, in aneighth implementation manner, the codeword sequence is a sequence with alength of 63 bits:

${d_{u}(n)} = ^{{- j}\frac{\pi \; {{un}{({n + 1})}}}{63}}$n = 0, 1, …  , 30, 31, 32, …  , 61, 62,

where

a value of u is 25, 29, or 34, and three different codeword sequencesare generated separately.

According to a fourth aspect, an embodiment of the present inventionfurther provides user equipment, including:

a receiving module, configured to receive a synchronization signal sentby first user equipment; and

a determining module, configured to determine a priority parameteraccording to a resource carrying the synchronization signal and acorrespondence between the resource and the priority parameter of thesynchronization signal, and determine a synchronization signal for thesecond user equipment according to the priority parameter.

In a first implementation manner of the fourth aspect, synchronizationsignals with different priority parameters are carried by usingdifferent resources.

With reference to the first implementation manner of the fourth aspect,in a second implementation manner, the priority parameter includes atleast one of a level and a layer, where the level is used to identify asource of the synchronization signal or used to identify precision ofthe synchronization signal; and the layer is used to identify aforwarding level of the synchronization signal; and the synchronizationsignals with different priority parameters are specificallysynchronization signals that differ in at least one of the level and thelayer.

With reference to the fourth aspect, the first implementation manner,and the second implementation manner, in a third implementation manner,the source of the synchronization signal includes: a global satellitepositioning system, a network device, or the first user equipment.

With reference to the fourth aspect, the first implementation manner,the second implementation manner, and the third implementation manner,in a fourth implementation manner, the resource includes: a time domainresource, a frequency domain resource, and a codeword resource; and thedifferent resources are specifically resources that differ in at leastone of a time domain, a frequency domain, and a codeword.

With reference to the fourth aspect, the first implementation manner,the second implementation manner, the third implementation manner, andthe fourth implementation manner, in a fifth implementation manner, thattime domain resources carrying the synchronization signals are differentincludes at least one of the following: serial numbers of data framesare different; serial numbers of timeslots carrying the synchronizationsignals are different; serial numbers of subframes carrying thesynchronization signals are different; and serial numbers of OFDMsymbols carrying the synchronization signals are different.

With reference to the fourth aspect, the first implementation manner,the second implementation manner, the third implementation manner, thefourth implementation manner, and the fifth implementation manner, in asixth implementation manner, that frequency domain resources carryingthe synchronization signals are different includes at least one of thefollowing: serial numbers of PRBs carrying the synchronization signalsare different; serial numbers of subcarriers carrying thesynchronization signals are different; and serial numbers of subcarriersin a subcarrier group carrying the synchronization signals aredifferent.

With reference to the fourth aspect, the first implementation manner,the second implementation manner, the third implementation manner, thefourth implementation manner, the fifth implementation manner, and thesixth implementation manner, in a seventh implementation manner, theresources that differ in a codeword are specifically resources thatdiffer in a codeword sequence.

With reference to the fourth aspect, the first implementation manner,the second implementation manner, the third implementation manner, thefourth implementation manner, the fifth implementation manner, the sixthimplementation manner, and the seventh implementation manner, in aneighth implementation manner, the codeword sequence is a sequence with alength of 63 bits:

${d_{u}(n)} = ^{{- j}\frac{\pi \; {{un}{({n + 1})}}}{63}}$n = 0, 1, …  , 30, 31, 32, …  , 61, 62,

where

a value of u is 25, 29, or 34.

According to a fifth aspect, an embodiment of the present inventionfurther provides user equipment, including: a transceiver and aprocessor, where

the processor is configured to determine a priority parameter of asynchronization signal and determine, according to the priorityparameter, a resource for carrying the synchronization signal, where aconfiguration of the resource indicates the priority parameter; and

the transceiver is configured to send the synchronization signal toanother user equipment by using the resource, so that the another userequipment determines a synchronization signal for the another userequipment.

In a first implementation manner of the fifth aspect, the processor isspecifically configured to: determine different resources to carrysynchronization signals with different priority parameters.

In the first implementation manner of the fifth aspect, the priorityparameter includes at least one of a level and a layer, where the levelis used to identify a source of the synchronization signal or used toidentify precision of the synchronization signal; and the layer is usedto identify a forwarding level of the synchronization signal; and thesynchronization signals with different priority parameters arespecifically synchronization signals that differ in at least one of thelevel and the layer.

With reference to the fifth aspect, the first implementation manner, andthe second implementation manner, in a third implementation manner, thesource of the synchronization signal includes: a global satellitepositioning system, a network device, or the user equipment.

With reference to the fifth aspect, the first implementation manner, thesecond implementation manner, and the third implementation manner, in afourth implementation manner, the resource includes: a time domainresource, a frequency domain resource, and a codeword resource; and thedifferent resources are specifically resources that differ in at leastone of a time domain, a frequency domain, and a codeword.

With reference to the fifth aspect, the first implementation manner, thesecond implementation manner, the third implementation manner, and thefourth implementation manner, in a fifth implementation manner, thattime domain resources carrying the synchronization signals are differentincludes at least one of the following: serial numbers of data framescarrying the synchronization signals are different; serial numbers oftimeslots carrying the synchronization signals are different; serialnumbers of subframes carrying the synchronization signals are different;and serial numbers of OFDM symbols carrying the synchronization signalsare different.

With reference to the fifth aspect, the first implementation manner, thesecond implementation manner, the third implementation manner, thefourth implementation manner, and the fifth implementation manner, in asixth implementation manner, that frequency domain resources carryingthe synchronization signals are different includes at least one of thefollowing: serial numbers of PRBs carrying the synchronization signalsare different; serial numbers of subcarriers carrying thesynchronization signals are different; and serial numbers of subcarriersin a subcarrier group carrying the synchronization signals aredifferent.

With reference to the fifth aspect, the first implementation manner, thesecond implementation manner, the third implementation manner, thefourth implementation manner, the fifth implementation manner, and thesixth implementation manner, in a seventh implementation manner, theresources that differ in a codeword are specifically resources thatdiffer in a codeword sequence.

With reference to the fifth aspect, the first implementation manner, thesecond implementation manner, the third implementation manner, thefourth implementation manner, the fifth implementation manner, the sixthimplementation manner, the seventh implementation manner, and an eighthimplementation manner, in a ninth implementation manner, the codewordsequence is a sequence with a length of 63 bits:

${d_{u}(n)} = ^{{- j}\frac{\pi \; {{un}{({n + 1})}}}{63}}$n = 0, 1, …  , 30, 31, 32, …  , 61, 62,

where

a value of u is 25, 29, or 34, and three different codeword sequencesare generated separately.

According to a sixth aspect, an embodiment of the present inventionfurther provides user equipment, including: a transceiver and aprocessor, where

the transceiver is configured to receive a synchronization signal sentby another user equipment; and

the processor is configured to determine a priority parameter accordingto a resource carrying the synchronization signal and a correspondencebetween the resource and the priority parameter of the synchronizationsignal, and determine a synchronization signal for the user equipmentaccording to the priority parameter.

In a first implementation manner of the sixth aspect, synchronizationsignals with different priority parameters are carried by usingdifferent resources.

With reference to the first implementation manner of the sixth aspect,in a second implementation manner, the priority parameter includes atleast one of a level and a layer, where the level is used to identify asource of the synchronization signal or used to identify precision ofthe synchronization signal; and the layer is used to identify aforwarding level of the synchronization signal; and the synchronizationsignals with different priority parameters are specificallysynchronization signals that differ in at least one of the level and thelayer.

With reference to the sixth aspect, the first implementation manner, andthe second implementation manner, in a third implementation manner, thesource of the synchronization signal includes: a global satellitepositioning system, a network device, or the first user equipment.

With reference to the sixth aspect, the first implementation manner, thesecond implementation manner, and the third implementation manner, in afourth implementation manner, the resource includes: a time domainresource, a frequency domain resource, and a codeword resource; and thedifferent resources are specifically resources that differ in at leastone of a time domain, a frequency domain, and a codeword.

With reference to the sixth aspect, the first implementation manner, thesecond implementation manner, the third implementation manner, and thefourth implementation manner, in a fifth implementation manner, thattime domain resources carrying the synchronization signals are differentincludes at least one of the following: serial numbers of data framesare different; serial numbers of timeslots carrying the synchronizationsignals are different; serial numbers of subframes carrying thesynchronization signals are different; and serial numbers of OFDMsymbols carrying the synchronization signals are different.

With reference to the sixth aspect, the first implementation manner, thesecond implementation manner, the third implementation manner, thefourth implementation manner, and the fifth implementation manner, in asixth implementation manner, that frequency domain resources carryingthe synchronization signals are different includes at least one of thefollowing: serial numbers of PRBs carrying the synchronization signalsare different; serial numbers of subcarriers carrying thesynchronization signals are different; and serial numbers of subcarriersin a subcarrier group carrying the synchronization signals aredifferent.

With reference to the sixth aspect, the first implementation manner, thesecond implementation manner, the third implementation manner, thefourth implementation manner, the fifth implementation manner, and thesixth implementation manner, in a seventh implementation manner, theresources that differ in a codeword are specifically resources thatdiffer in a codeword sequence.

With reference to the sixth aspect, the first implementation manner, thesecond implementation manner, the third implementation manner, thefourth implementation manner, the fifth implementation manner, the sixthimplementation manner, and the seventh implementation manner, in aneighth implementation manner, the codeword sequence is a sequence with alength of 63 bits:

${d_{u}(n)} = ^{{- j}\frac{\pi \; {{un}{({n + 1})}}}{63}}$n = 0, 1, …  , 30, 31, 32, …  , 61, 62,

where

a value of u is 25, 29, or 34.

According to the synchronization signal carrying method and the userequipment that are provided in the embodiments of the present invention,user equipment determines a priority parameter of a synchronizationsignal, determines, according to the priority parameter, a resource forcarrying the synchronization signal, and further sends thesynchronization signal by using the determined resource. In this way,user equipment receiving the synchronization signal can identifysynchronization signals with different priority parameters according toresources carrying the synchronization signals, and the user equipmentreceiving the synchronization signal can determine a synchronizationsignal according to a priority parameter, and therefore, a determiningmanner is more flexible.

BRIEF DESCRIPTION OF DRAWINGS

To describe the technical solutions in the embodiments of the presentinvention or in the prior art more clearly, the following brieflyintroduces the accompanying drawings required for describing theembodiments. Apparently, the accompanying drawings in the followingdescription show some embodiments of the present invention, and personsof ordinary skill in the art may still derive other drawings from theseaccompanying drawings without creative efforts.

FIG. 1 is a flowchart of an embodiment of a synchronization signalcarrying method according to the present invention;

FIG. 2 is a flowchart of an embodiment of a synchronization signalcarrying method according to the present invention;

FIG. 3 is a schematic diagram of a configuration of a time domainresource in still another embodiment of a synchronization signalcarrying method according to the present invention;

FIG. 4 is a schematic diagram of a configuration of a frequency domainresource in still another embodiment of a synchronization signalcarrying method according to the present invention;

FIG. 5 is a schematic diagram of a configuration of a codeword resourcein still another embodiment of a synchronization signal carrying methodaccording to the present invention;

FIG. 6 is a schematic diagram of a configuration of a codeword resourcein still another embodiment of a synchronization signal carrying methodaccording to the present invention;

FIG. 7 is a schematic structural diagram of an embodiment of userequipment according to the present invention;

FIG. 8 is a schematic structural diagram of still another embodiment ofuser equipment according to the present invention;

FIG. 9 is a schematic structural diagram of still another embodiment ofuser equipment according to the present invention; and

FIG. 10 is a schematic structural diagram of still another embodiment ofuser equipment according to the present invention.

DESCRIPTION OF EMBODIMENTS

To make the objectives, technical solutions, and advantages of theembodiments of the present invention clearer, the following clearly andcompletely describes the technical solutions in the embodiments of thepresent invention with reference to the accompanying drawings in theembodiments of the present invention. Apparently, the describedembodiments are some but not all of the embodiments of the presentinvention. All other embodiments obtained by persons of ordinary skillin the art based on the embodiments of the present invention withoutcreative efforts shall fall within the protection scope of the presentinvention.

Technologies described in this specification may be applied to variouscommunications systems, for example, current 2G and 3G communicationssystems and a next-generation communications system, for example, aGlobal System for Mobile Communications (GSM, Global System for Mobilecommunications), a Code Division Multiple Access (CDMA, Code DivisionMultiple Access) system, a Time Division Multiple Access (TDMA, TimeDivision Multiple Access) system, Wideband Code Division Multiple Access(WCDMA, Wideband Code Division Multiple Access Wireless), a FrequencyDivision Multiple Access (FDMA, Frequency Division Multiple Addressing)system, an Orthogonal Frequency-Division Multiple Access (OFDMA,Orthogonal Frequency-Division Multiple Access) system, a Single-carrierFDMA (SC-FDMA) system, a General Packet Radio Service (GPRS, GeneralPacket Radio Service) system, a Long Term Evolution (LTE, Long TermEvolution) system, and other communications systems.

User equipment involved in this application may be a wireless terminalor a wired terminal. The wireless terminal may refer to a device thatprovides a user with voice and/or data connectivity, a handheld devicewith a wireless connection function, or another processing deviceconnected to a wireless modem. The wireless terminal may communicatewith one or more core networks by using a wireless access network (suchas RAN, Radio Access Network). The wireless terminal may be a mobileterminal, such as a mobile phone (or referred to as a “cellular” phone)and a computer with a mobile terminal, for example, may be a portable,pocket-sized, handheld, computer built-in, or in-vehicle mobileapparatus, which exchanges voice and/or data with the wireless accessnetwork. For example, it may be a device such as a personalcommunication service (PCS, Personal Communication Service) phone, acordless telephone set, a Session Initiation Protocol (SIP) phone, awireless local loop (WLL, Wireless Local Loop) station, or a personaldigital assistant (PDA, Personal Digital Assistant). The wirelessterminal may also be called a system, a subscriber unit (SubscriberUnit), a subscriber station (Subscriber Station), a mobile station(Mobile Station), a mobile station (Mobile), a remote station (RemoteStation), an access point (Access Point), a remote terminal (RemoteTerminal), an access terminal (Access Terminal), a user terminal (UserTerminal), a user agent (User Agent), a user device (User Device), oruser equipment (User Equipment).

A network device involved in the present application may be, forexample, a base station, a radio network controller (Radio NetworkController, RNC), or the like.

The base station (for example, an access point) may be a base station(BTS, Base Transceiver Station) in GSM or CDMA, may also be a basestation (NodeB) in WCDMA, and may further be an evolved NodeB (NodeB,eNB, or e-NodeB, evolutional Node B) in LTE, which is not limited in thethis application.

FIG. 1 is a flowchart of an embodiment of a synchronization signalcarrying method according to the present invention. As shown in FIG. 1,the method in this embodiment may include:

Step 101. First user equipment determines a priority parameter of asynchronization signal.

Step 102. The first user equipment determines, according to the priorityparameter, a resource for carrying the synchronization signal, where aconfiguration of the resource indicates the priority parameter.

Step 103. The first user equipment sends the synchronization signal tosecond user equipment by using the resource, so that the second userequipment determines a synchronization signal for the second userequipment.

Optionally, the priority parameter of the synchronization signal mayspecifically include at least one of a level and a layer.

As a feasible implementation manner, the level of the synchronizationsignal may be used to identify a source of the synchronization signal,and the source of the synchronization signal may specifically include aglobal navigation satellite system (Global Navigation Satellite System,GNSS for short), a network device, such as an eNodeB (eNodeB), or thefirst user equipment, such as a clock (local timing) of the first userequipment itself. For example, a synchronization signal coming from theGNSS may be considered as being of a first level, a synchronizationsignal coming from the eNodeB may be considered as being of a secondlevel, and a synchronization signal coming from the local timing may beconsidered as being of a third level. It may be set that: a priority ofthe first level is higher than that of the second level, a priority ofthe second level is higher than that of the third level, and so on.

As another feasible implementation manner, the level of thesynchronization signal may further be used to identify precision of thesynchronization signal. For example, a synchronization signal withprecision less than or equal to 0.1 ppm may be considered as being of afirst level; a synchronization signal with precision greater than 0.1ppm and less than or equal to 0.5 ppm may be considered as being of asecond level; and a synchronization signal with precision greater than0.5 ppm, or less than or equal to 1.0 ppm may be considered as being ofa third level; and a synchronization signal with precision greater than1.0 ppm may be considered as being of a fourth level. It may be setthat: a priority of the first level is higher than that of the secondlevel, a priority of the second level is higher than that of the thirdlevel, a priority of the third level is higher than that of the fourthlevel, and so on.

The above merely exemplarily provides a feasible level classificationmanner, but does not impose limitation on this embodiment of the presentinvention.

Optionally, the layer of the synchronization signal may be used toidentify a forwarding level of the synchronization signal. For example,in the foregoing example in which the first user equipment sends thesynchronization signal to the second user equipment, if thesynchronization signal is a synchronization signal generated by thefirst user equipment itself, the synchronization signal may beconsidered as being of a first layer; if the synchronization signal isgenerated by the first user equipment according to a synchronizationsignal generated by a third user equipment, in this case, asynchronization signal sent by the third user equipment to the firstuser equipment is considered as being of a first layer, and asynchronization signal sent by the first user equipment to the seconduser equipment is considered as being of a second layer; and so on. Itmay be set that: a priority of the first layer is higher than that ofthe second layer, a priority of the second layer is higher than that ofthe third layer, and so on.

It needs to be noted that synchronization signals with differentpriority parameters may be specifically synchronization signals thatdiffer in at least one of the level and the layer. That is, thesynchronization signals with different priority parameters may besynchronization signals that differ in the level, or may besynchronization signals that differ in the layer, or may besynchronization signals that differ in both the level and the layer.

In this embodiment of the present invention, after determining thepriority parameter of the synchronization signal, the first userequipment may determine, according to the different priority parametersof the synchronization signals, different resources for carrying.

The foregoing resource may include a time domain resource, a frequencydomain resource, and a codeword resource. The different resources may bespecifically resources that differ in at least one of a time domain, afrequency domain, and a codeword.

If all three of a time domain resource, a frequency domain resource, anda codeword resource that carry at least two synchronization signals arecompletely the same, the at least two synchronization signals may bedeemed as same synchronization signals. If the three resources of theforegoing at least two synchronization signals are not completely thesame, that is, at least one type of resource is different, the foregoingat least two synchronization signals are deemed as differentsynchronization signals.

Optionally, that time domain resources carrying the synchronizationsignals are different may include at least one of the following: serialnumbers of data frames carrying the synchronization signals aredifferent; serial numbers of timeslots carrying the synchronizationsignals are different; serial numbers of subframes carrying thesynchronization signals are different; and serial numbers of orthogonalfrequency division multiplexing OFDM symbols carrying thesynchronization signals are different.

Optionally, that frequency domain resources carrying the synchronizationsignals are different includes at least one of the following: serialnumbers of PRBs carrying the synchronization signals are different;serial numbers of subcarriers carrying the synchronization signals aredifferent; and serial numbers of subcarriers in a subcarrier groupcarrying the synchronization signals are different. That serial numbersof subcarriers in a subcarrier group carrying the synchronizationsignals are different is illustrated by using the following example: iftwo subcarrier groups separately include three subcarriers, where serialnumbers of three subcarriers in one subcarrier group are, for example,1, 2, and 3 separately, and serial numbers of three subcarriers inanother subcarrier group are, for example, 1, 3, and 4 separately,because a serial number of one subcarrier in one subcarrier group isdifferent from a serial number of one subcarrier in the other subcarriergroup (2 and 4 are different serial numbers), it is deemed that theserial numbers of the subcarriers in the two subcarrier groups aredifferent. That is, it can be deemed that serial numbers of subcarriersin at least two subcarrier groups are different provided that a serialnumber of one subcarrier in one of the at least two subcarrier groups isdifferent from a serial number of one subcarrier in another subcarriergroup in the at least two subcarrier groups.

Optionally, the resources that differ in a codeword may be specificallyresources that differ in a codeword sequence.

After determining the priority parameter of the synchronization signal,the first user equipment may further determine to use which type ofresource and which resource configuration manner to carry thesynchronization signal, so that second user equipment that receives thesynchronization signal can learn of the priority parameter correspondingto the synchronization signal, and determine a synchronization signalfor the second user equipment accordingly.

In the synchronization signal carrying method according to thisembodiment, user equipment determines a priority parameter of asynchronization signal, determines, according to the priority parameter,a resource for carrying the synchronization signal, and further sendsthe synchronization signal by using the determined resource. In thisway, user equipment receiving the synchronization signal can identifysynchronization signals with different priority parameters according toresources carrying the synchronization signals, and the user equipmentreceiving the synchronization signal can determine a synchronizationsignal according to a priority parameter, thereby improving flexibilityof a synchronization signal determining manner. In addition, because thepriority parameter may be at least one of a level and a layer, where thelevel may express a source or precision of the synchronization signal,and the layer may express a forwarding level of the synchronizationsignal, the user equipment receiving the synchronization signal candetermine the synchronization signal for the user equipment itselfaccording to the source, the precision, or the forwarding level of thesynchronization signal. This determining manner is more specific, sothat the user equipment receiving the synchronization signal can selecta more suitable synchronization signal.

FIG. 2 is a flowchart of still another embodiment of a synchronizationsignal carrying method according to the present invention. As shown inFIG. 2, the method includes:

S201. Second user equipment receives a synchronization signal sent byfirst user equipment.

S202. The second user equipment determines a priority parameteraccording to a resource carrying the synchronization signal and acorrespondence between the resource and the priority parameter of thesynchronization signal.

S203. The second user equipment determines a synchronization signal forthe second user equipment according to the priority parameter.

Synchronization signals with different priority parameters may becarried by using different resources. That is, there is a correspondencebetween the resource carrying the synchronization signal and thepriority parameter of the synchronization signal. Therefore, afterreceiving the synchronization signal sent by the first user equipment,the second user equipment may determine a priority of thesynchronization signal according to the resource carrying thesynchronization signal and the correspondence between the resource andthe priority parameter of the synchronization signal, where thecorrespondence may be determined by one or both of the first userequipment and the second user equipment. After the determining, both thefirst user equipment and the second user equipment can acquire thecorrespondence. Multiple manners of acquiring or storing thecorrespondence are available, and this embodiment does not imposelimitation on the present invention.

It can be understood that there are multiple manners for the second userequipment to determine a synchronization signal for the second userequipment itself. For example, the second user equipment may select asynchronization signal with a highest priority from all receivedsynchronization signals according to priority parameters of thesesynchronization signals, as the synchronization signal for the seconduser equipment itself, or may also use another manner. This embodimentdoes not impose limitation on the present invention. Optionally, thepriority parameter of the synchronization signal may specificallyinclude at least one of a level and a layer.

As a feasible implementation manner, the level of the synchronizationsignal may be used to identify a source of the synchronization signal,and the source of the synchronization signal may specifically include aGNSS, a network device, or the foregoing first user equipment. It can beunderstood that for a synchronization signal, there is merely onesource, and for all synchronization signals in a communications system,a source of each of the synchronization signals may be any one of theforegoing three sources. The foregoing sources are merely examples andthere may further be another source. Specifically, different sources ofsynchronization signals may be distinguished by a first level, a secondlevel, a third level, and so on. It may be set that: a priority of thefirst level is higher than that of the second level, a priority of thesecond level is higher than that of the third level, and so on.

As another feasible implementation manner, the level of thesynchronization signal may further be used to identify precision of thesynchronization signal. Synchronization signals may be classified intolevels according to an order of precision. For example, differentsources of synchronization signals are distinguished by classifying thesources into a first level, a second level, a third level, and so on: asynchronization signal with precision less than or equal to 0.1 ppm maybe considered as being of the first level; a synchronization signal withprecision greater than 0.1 ppm and less than or equal to 0.5 ppm may beconsidered as being of the second level; a synchronization signal withprecision greater than 0.5 ppm, or less than or equal to 1.0 ppm may beconsidered as being of the third level; a synchronization signal withprecision greater than 1.0 ppm may be considered as being of a fourthlevel. It may be set that: a priority of the first level is higher thanthat of the second level, a priority of the second level is higher thanthat of the third level, and so on.

For details about the level of the synchronization signal, reference maybe made to related descriptions in the embodiment shown in FIG. 1, anddetails are not described herein again.

The above merely exemplarily provides a feasible level classificationmanner, but does not impose limitation on this embodiment of the presentinvention.

Optionally, the layer of the synchronization signal may be used toidentify a forwarding level of the synchronization signal. For example:user equipment A generates a synchronization signal according to asynchronization signal generated by another user equipment B. In thiscase, the synchronization signal generated by the user equipment A isone layer lower than the synchronization signal generated by the userequipment B. Specifically, different layers may be expressed by using afirst layer, a second layer, a third layer, and so on. It may be setthat: a priority of the first layer is higher than that of the secondlayer, a priority of the second layer is higher than that of the thirdlayer, and so on.

For details about the layer of the synchronization signal, reference maybe made to related descriptions in the embodiment shown in FIG. 1, anddetails are not described herein again.

It needs to be noted that synchronization signals with differentpriority parameters may be specifically synchronization signals thatdiffer in at least one of the level and the layer. That is, thesynchronization signals with different priority parameters may besynchronization signals that differ in the level, or may besynchronization signals that differ in the layer, or may besynchronization signals that differ in both the level and the layer.

Optionally, the resource carrying the synchronization signal may includea time domain resource, a frequency domain resource, and a codewordresource. The different resources may be specifically resources thatdiffer in at least one of a time domain, a frequency domain, and acodeword.

If all three of a time domain resource, a frequency domain resource, anda codeword resource that carry at least two synchronization signals arecompletely the same, the at least two synchronization signals may bedeemed as same synchronization signals. If the three resources of theforegoing at least two synchronization signals are not completely thesame, that is, at least one type of resource is different, the foregoingat least two synchronization signals are deemed as differentsynchronization signals.

Optionally, that time domain resources carrying the synchronizationsignals are different may include at least one of the following: serialnumbers of data frames carrying the synchronization signals aredifferent; serial numbers of timeslots carrying the synchronizationsignals are different; serial numbers of subframes carrying thesynchronization signals are different; and serial numbers of OFDMsymbols carrying the synchronization signals are different.

Optionally, that frequency domain resources carrying the synchronizationsignals are different includes at least one of the following: serialnumbers of PRBs carrying the synchronization signals are different;serial numbers of subcarriers carrying the synchronization signals aredifferent; and serial numbers of subcarriers in a subcarrier groupcarrying the synchronization signals are different.

Optionally, the resources that differ in a codeword may be specificallyresources that differ in a codeword sequence.

In a communications system, a correspondence between the resource andthe priority parameter of the synchronization signal may be preset. Eachuser equipment in the communications system may learn of the foregoingcorrespondence in advance, and then, after receiving the synchronizationsignal, the second user equipment can determine a priority of thesynchronization signal according to the resource carrying thesynchronization signal and the correspondence.

Further, after determining the priority parameter corresponding to thesynchronization signal, the second user equipment determines asynchronization signal for the second user equipment accordingly.Optionally, if the second user equipment generates a synchronizationsignal according to the synchronization signal sent by the first userequipment, a level of the synchronization signal generated by the seconduser equipment may be the same as a level of the synchronization signalof the first user equipment, and a layer of the synchronization signalgenerated by the second user equipment is one layer lower than that ofthe synchronization signal of the first user equipment.

In the synchronization signal carrying method according to thisembodiment of the present invention, after receiving a synchronizationsignal sent by another user equipment, user equipment determines apriority parameter of the synchronization signal according to a resourcecarrying the synchronization signal and a correspondence between theresource and the priority parameter of the synchronization signal, anddetermines a synchronization signal for the user equipment itselfaccording to the priority parameter, thereby improving flexibility of asynchronization signal determining manner. In addition, because thepriority parameter may be at least one of a level and a layer, where thelevel may express a source or precision of the synchronization signal,and the layer may express a forwarding level of the synchronizationsignal, the user equipment receiving the synchronization signal candetermine the synchronization signal for the user equipment itselfaccording to the source, the precision, or the forwarding level of thesynchronization signal. This determining manner is more specific, sothat the user equipment receiving the synchronization signal can selecta more suitable synchronization signal.

The following uses specific embodiments to describe in detail thetechnical solutions of the method embodiments shown in FIG. 1 and FIG.2.

In an embodiment of a synchronization signal carrying method provided inthe present invention, synchronization signals with different priorityparameters may be distinguished by using different time domainresources.

Herein, a time domain resource for sending a synchronization signal maybe a data frames, a subframe, a timeslots, or an orthogonal frequencydivision multiplexing OFDM symbol, for sending a synchronization signal.Distinguishing between synchronization signals with different priorityparameters according to different time domain resources may bedistinguishing between signals and the synchronization signals withdifferent priority parameters by sending the synchronization signals indata frames with different serial numbers, subframes with differentserial numbers, timeslots with different serial numbers, OFDM symbolswith different serial numbers, or any combination of the foregoing fourresources.

The following uses an example in which synchronization signals withdifferent priority parameters are distinguished by using differentsubframes with different serial numbers. It can be understood that theexample may be extended to that synchronization signals with differentpriority parameters are distinguished by using data frames, timeslots,or OFDM symbols.

As shown in FIG. 3, it is assumed that one data frame includes 10subframes, and serial numbers of the 10 subframes are 1, 2, 3, 4, 5, 6,7, 8, 9, and 10 separately. One data frame may carry one or moresynchronization sequences and the one or more synchronization sequencesare used to carry a same synchronization signal. Generally, one dataframe may carry two synchronization sequences, and the twosynchronization sequences are used to carry a same synchronizationsignal. The following is described by using an example in which one dataframe carries two synchronization sequences. It is assumed that a firstsynchronization sequence of the synchronization signal is carried on thefirst subframe. In this implementation scenario, differentsynchronization signals are distinguished by the following several typesof subframe configurations: {1, 2}, {1, 3}, {1, 4}, and {1, 5}, where{1, 2} expresses that one synchronization sequence is carried on thefirst subframe (that is, a serial number of the subframe in the dataframes is 1) and the other synchronization sequence is carried on thesecond subframe (that is, a serial number of the subframe in the dataframes is 2). {1, 3} expresses that one synchronization sequence iscarried on the first subframe and the other synchronization sequence iscarried on the third subframe.

The foregoing several types of different subframe resourceconfigurations correspond to synchronization signals with differentpriority parameters. Because both a user sending the synchronizationsignals and user equipment receiving the synchronization signals canlearn (for example, from local storage or by acquiring from anotherdevice) of a correspondence between subframe resource configurations andpriority parameters, the user equipment receiving the synchronizationsignals can distinguish between synchronization signals with differentpriority parameters according to subframe resources carrying thesynchronization signals and the correspondence between the subframeresource configurations and the priority parameters. In an actualsystem, a required quantity may be determinably determined from theforegoing several time configurations to represent priority parametersof the required quantity of synchronization signals.

Further, it is assumed that N data subframes are included in a dataframe, where N is an integer greater than 0. The example in which onedata frame carries two synchronization sequences is still used fordescription (both the two synchronization sequences carry a samesynchronization signal), where one synchronization sequence is carriedin the first subframe. In this implementation scenario, synchronizationsignals with different priority parameters may be distinguished by usingthe following ceil(N/2)−1 types of subframe configuration manners: {1,2}, {1, 3}, . . . , and {1, ceil(N/2)}, where Ceil( ) is an operationfor rounding up to the nearest integer. {1, 2} expresses that one of thesynchronization sequences is carried on the first subframe, and theother is carried on the second subframe. Ceil(N/2)−1 synchronizationsignals with different priority parameters may be distinguished by usingceil(N/2)−1 types of different subframe resource configurations. In anactual system, a required quantity may be determinably determined fromthe ceil(N/2)−1 time configurations to represent priority parameters ofthe required quantity of synchronization signals.

In this embodiment, user equipment determines a priority parameter of asynchronization signal, determines, according to the priority parameter,a subframe resource for carrying the synchronization signal, and furthersends the synchronization signal by using the determined subframeresource. In this way, user equipment receiving the synchronizationsignal can identify synchronization signals with different priorityparameters according to subframe resources carrying the synchronizationsignals, and the user equipment receiving the synchronization signal candetermine a synchronization signal according to a priority parameter,thereby improving flexibility of a synchronization signal determiningmanner. In addition, because the priority parameter may be at least oneof a level and a layer, where the level may express a source orprecision of the synchronization signal, and the layer may express aforwarding level of the synchronization signal, the user equipmentreceiving the synchronization signal can determine the synchronizationsignal for the user equipment itself according to the source, theprecision, or the forwarding level of the synchronization signal. Thisdetermining manner is more specific, so that the user equipmentreceiving the synchronization signal can select a more suitablesynchronization signal.

In an embodiment of a synchronization signal carrying method provided inthe present invention, synchronization signals with different priorityparameters may be distinguished by using different frequency resources.

The frequency resources may be frequencies occupied for sending thesynchronization signals. In a Long Term Evolution (Long Term Evolution,LTE) system, a frequency resource may be a physical resource block pair(Physical Resource Block, PRB pair) or a single subcarrier or asubcarrier group in a PRB pair. Synchronization signals with differentpriority parameters are distinguished by using different frequencyresources. That is, the synchronization signals with different priorityparameters are distinguished by sending the synchronization signals onPRB pairs with different serial numbers, subcarriers with differentserial numbers, or subcarriers with different serial numbers in asubcarrier group.

The following uses an example in which synchronization signals withdifferent priority parameters are distinguished by using PRB pairs withdifferent serial numbers. It can be understood that the example may beextended to that synchronization signals with different priorityparameters are distinguished by subcarriers with different serialnumbers, or subcarriers with different serial numbers in a subcarriergroup.

As shown in FIG. 4, it is assumed that a bandwidth of a system is 50 PRBpairs and sending one synchronization signal needs to occupy sixconsecutive PRBs. In this implementation scenario, there are a maximumof seven configurations of six distinguishable consecutive PRBs forsynchronization signals with different priority parameters. Sevensynchronization signals with different priority parameters can bedistinguished by using the seven resource configurations of differentPRB pair resources. In an actual system, a required quantity may beselectively determined from the seven frequency configurations torepresent priority parameters of the required quantity ofsynchronization signals.

As shown in FIG. 4, three available physical resources f1, f2, and f3 ina system may be used to carry a synchronization signal in the system.Each physical resource may include one or more PRB pairs, wheredifferent physical resources consist of different PRB pairs, and PRBpairs between the physical resources may not overlap or may partiallyoverlap. Then, f1, f2, and f3 may be used to separately carrysynchronization signals with different priority parameters.

Further, it is assumed that N PRB pairs are included in a data frame,where N is an integer greater than 0, and M consecutive PRB pairs needto be occupied for sending a synchronization signal, where M is aninteger greater than 0. In this implementation scenario, there arefloor(N/M) distinguishable PRB pair configurations of synchronizationsignals with different priority parameters, where Floor( ) expresses anoperation for rounding down to the nearest integer. Floor(N/M)synchronization signals with different priority parameters can bedistinguished by using the floor(N/M) different frequency resourceconfigurations. In an actual system, a required quantity may beselectively determined from the floor(N/M) frequency configurations torepresent priority parameters of the required quantity ofsynchronization signals.

In this embodiment, user equipment determines a priority parameter of asynchronization signal, determines, according to the priority parameter,a PRB pair for carrying the synchronization signal, and further sendsthe synchronization signal by using the determined PRB pair. In thisway, user equipment receiving the synchronization signal can identifysynchronization signals with different priority parameters according toPRB pairs carrying the synchronization signals, and the user equipmentreceiving the synchronization signal can determine a synchronizationsignal according to a priority parameter, thereby improving flexibilityof a synchronization signal determining manner. In addition, because thepriority parameter may be at least one of a level and a layer, where thelevel may express a source or precision of the synchronization signal,and the layer may express a forwarding level of the synchronizationsignal, the user equipment receiving the synchronization signal candetermine the synchronization signal for the user equipment itselfaccording to the source, the precision, or the forwarding level of thesynchronization signal. This determining manner is more specific, sothat the user equipment receiving the synchronization signal can selecta more suitable synchronization signal.

In an embodiment of a synchronization signal carrying method provided inthe present invention, synchronization signals with different priorityparameters may be distinguished by using different codeword resources.

The codeword resources may be codeword sequences used for sending thesynchronization signals. Distinguishing between priority parameters ofsynchronization signals depending on codeword sequences isdistinguishing between the priority parameters of the signals by sendingthe synchronization signals in different codeword sequences. Generally,one synchronization signal may be corresponding to one or moresynchronization sequences and one synchronization sequence may becarried using one or more codeword sequences, where multiple codewordsequences may be located in different symbols.

It is assumed that there are three available codewords, for example,sequences with a length of 63 bits, in a system:

${d_{u}(n)} = ^{{- j}\frac{\pi \; {{un}{({n + 1})}}}{63}}$n = 0, 1, …  , 30, 31, 32, …  , 61, 62,

where

a value of u is 25, 29, or 34, and three different codeword sequencesare generated separately. That is, different codeword sequences may begenerated by using different values of u, where three codeword sequencesobtained by using the value 25, 29, or 34 of u have good correlationproperties.

In this implementation scenario, three different synchronization signalsmay be distinguished by using the three different codeword sequences. Inan actual system, a required quantity may be selectively determined fromthe three codeword sequences to represent priority parameters of therequired quantity of synchronization signals.

As shown in FIG. 5, 10 subframes are included in one data frame and eachof the 10 subframes includes a same quantity of symbols, for example,there may be 14 symbols, 13 symbols, and 12 symbols. It is assumed thatin a subframe carrying a synchronization signal among the 10 subframes,two symbols carry one synchronization signal and one symbol carries onesynchronization sequence, where one synchronization signal correspondsto two synchronization sequences. For example: As shown in FIG. 5, in asubframe including 14 symbols, one synchronization sequence may becarried by using symbol 1, and the other synchronization sequence may becarried by using symbol 5. In a subframe including 13 symbols, onesynchronization sequence may be carried by using symbol 1, and the othersynchronization sequence may be carried by using symbol 5. In a subframeincluding 12 symbols, one synchronization sequence may be carried byusing symbol 1 and the other synchronization sequence may be carried byusing symbol 4. If there are three synchronization sequences that can becarried in a symbol, there may be a total of 3*3=9 differentconfigurations of carrying synchronization sequences in two symbols.That is, there are nine distinguishable priority parameters ofsynchronization signals, and therefore, nine different priorityparameters can be distinguished.

In addition, in the foregoing example, it can be seen that spacingsbetween two carrying symbols that carry a same synchronization signalare {3}, {3}, and {2} separately, where that a spacing is {3} expressesthat a spacing is three symbols, and if a spacing is {0}, it expressesthat two symbols are adjacent and no other symbols exist between the twosymbols. In an actual system, if a quantity of symbols is 14, accordingto needs of the system, a spacing between two carrying symbols thatcarry a same synchronization signal may be any value in {0}, {1}, {2},{3}, {4}, {5}, {6}, {7}, {8}, {9}, {10}, {11}, and {12}.

Further, as shown in FIG. 6, 10 subframes are included in one data frameand each of the 10 subframes includes a same quantity of symbols, theremay be 14 symbols, 13 symbols, and 12 symbols. In a subframe carrying asynchronization signal among the 10 subframes, three symbols carry onesynchronization signal and each symbol is used to carry onesynchronization sequence, that is, one synchronization signalcorresponds to three synchronization sequences. For example, as shown inFIG. 6, in a subframe including 14 symbols, one synchronization sequencemay be carried by using symbol 1, another synchronization sequence maybe carried by using symbol 7, and still another synchronization sequencemay be carried by using a symbol 13. In a subframe including 13 symbols,one synchronization sequence may be carried by using symbol 1, anothersynchronization sequence may be carried by using symbol 5, and stillanother synchronization sequence may be carried by using symbol 13. In asubframe including 12 symbols, one synchronization sequence may becarried by using symbol 1, another synchronization sequence may becarried by using symbol 6, and still another synchronization sequencemay be carried by using symbol 11. If there are three synchronizationsequences that can be carried in a symbol, there may be a total of3*3*3=27 different configurations of carrying synchronization sequencesin two symbols. That is, there may be 27 distinguishable synchronizationsignals, and therefore, 27 different priority parameters may bedistinguished.

In addition, in the foregoing example, we see that spacings between twocarrying symbols that carry a same synchronization signal are {5}, {5},and {4} separately, where that a spacing is {5} expresses that a spacingis five symbols, and if a spacing is {0}, it expresses that two symbolsare adjacent and no other symbols exist between the two symbols. In anactual system, if a quantity of symbols is 14, according to needs of thesystem, a spacing between two carrying symbols that carry a samesynchronization signal may be any one of {0}, {1}, {2}, {3}, {4}, {5},{6}, {7}, {8}, {9}, {10}, {11}, and {12}.

Further, it is assumed that there are N available codeword sequences ina system. N different priority parameters of synchronization signals maybe distinguished by using the N different codeword sequences. In anactual system, a required quantity may be selectively determined fromconfigurations of the N codeword sequences to represent priorityparameters of the required quantity of synchronization signals.

In this embodiment, user equipment determines a priority parameter of asynchronization signal, determines, according to the priority parameter,a codeword sequence for carrying the synchronization signal, and furthersends the synchronization signal by using the determined codewordsequence. In this way, user equipment receiving the synchronizationsignal can identify synchronization signals with different priorityparameters according to codeword sequences carrying the synchronizationsignals, and the user equipment receiving the synchronization signal canselect a synchronization signal according to a priority parameter,thereby improving flexibility of a synchronization signal determiningmanner. Because the priority parameter may be at least one of a leveland a layer, where the level may express a source or precision of thesynchronization signal, and the layer may express a forwarding level ofthe synchronization signal, the user equipment receiving thesynchronization signal can determine the synchronization signal for theuser equipment itself according to the source, the precision, or theforwarding level of the synchronization signal. This determining manneris more specific, so that the user equipment receiving thesynchronization signal can select a more suitable synchronizationsignal.

In an embodiment of a synchronization signal carrying method provided inthe present invention, synchronization signals with different priorityparameters may be distinguished by using different time domain resourcesand frequency domain resources.

The time resources herein may be data frames, subframes, timeslots, orOFDM symbols, for sending synchronization signals. The frequencyresources may be frequencies occupied for sending the synchronizationsignals. In an LTE system, a frequency resource may be a PRB pair, ormay be a single subcarrier or a subcarrier group in a PRB pari.Distinguishing between priority parameters of synchronization signalsaccording to time resources and frequency resources is distinguishingbetween the priority parameters of synchronization signals by sendingthe synchronization signals in data frames with different serialnumbers, subframes with different serial numbers in a data frame,timeslots with different serial numbers, and OFDM symbols with differentserial numbers, by using PRBs with different serial numbers, subcarrierswith different serial numbers, or subcarriers with different serialnumbers in a subcarrier group.

In an example in which synchronization signals with different priorityparameters are distinguished by using subframes with different serialnumbers in a data frame and PRB pairs with different serial numbers, theexample may be extended to that priority parameters of synchronizationsignals are distinguished by using data frames with different serialnumbers and using subcarriers or subcarrier groups in a PRB pair, or byusing OFDM symbols with different serial numbers and using subcarriersor subcarrier groups in a PRB pair.

It is assumed that 10 subframes are included in a data frame in asystem, and it is assumed that two synchronization sequences are carriedin one data frame, where the two synchronization sequences carry a samesynchronization signal and one synchronization sequence is carried inthe first subframe or carried in the sixth subframe. In addition, it isassumed that two different PRB configurations in the system are used tocarry a synchronization signal, for example, a first PRB configurationincludes the first to the sixth PRB pairs and a second PRB configurationincludes the seventh to twelfth PRB pairs. In the first five subframes,a synchronization signal is carried by using the first PRBconfiguration, and in the last five subframes, a synchronization signalis carried by using the second PRB configuration. In this implementationscenario, the following 17 distinguishable combinations ofconfigurations of a subframe and a PRB for carrying a synchronizationsignal are available: {1(f1),2(f1)}, {1(f1),3(f1)}, {1(f1),4(f1)},{1(f1),5(f1)}, {6(f2,7(f2)}, {6(f2),8(f2)}, {6(f2),9(f2)},{6(f2),10(f2)}, {1(f1),6(f2)}, {1(f1),7(f2)}, {1(f1),8(f2)},{1(f1),9(f2)}, {1(f1),10(f2)}, {2(f1),6(f2)}, {3(f1),6(f2)},{4(f1),6(f2)}, and {5(f1),6(f2)}, where {1(f1),2(f1)} expresses that asynchronization signal is carried by using the first PRB configurationin the first subframe and carried by using the first PRB configurationin the second subframe, and {1(f1),6(f2)} expresses that asynchronization signal is carried by using the first PRB configurationin the first subframe and carried by using the second PRB configurationin the sixth subframe. 17 different priority parameters ofsynchronization signals can be distinguished by using the 17 differentconfigurations of a subframe resource and a PRB pair resource. In anactual system, a required quantity may be selectively determined fromthe 17 time configurations to represent priority parameters of therequired quantity of synchronization signals. It can be understood thatthe first PRB in a subframe is selected in all the foregoing 17configurations, but in actual determining, it is not necessary that thefirst PRB of each subframe is selected. In this case, a quantity ofresource configurations that can be obtained is greater than 17.

Further, it is assumed that 2*N subframes are included in a data framein a system, and it is assumed that a total of two synchronizationsequences are carried in one data frame, where the two synchronizationsequences carry a same synchronization signal and one synchronizationsequence is carried in the first subframe or carried in the (N+1)thsubframe, where N is an integer greater than 0. In addition, it isassumed that two different PRB configurations in the system are used tocarry a synchronization signal, for example, in the first N subframes, asynchronization signal is carried by using a first PRB configuration;and in the last N subframes, a synchronization signal is carried byusing a second PRB configuration. Under this condition, 4*N−3distinguishable configurations of a subframe and a PRB that carry asynchronization signal are available. 4*N−3 different priorityparameters of synchronization signals can be distinguished by using the4*N−3 different configurations of a subframe resource and a PRBresource. In an actual system, a required quantity may be selectivelydetermined from the 4*N−3 time configurations to represent priorityparameters of the required quantity of synchronization signals.

In this embodiment, user equipment determines a priority parameter of asynchronization signal, determines, according to the priority parameter,a subframe and a PRB pair for carrying the synchronization signal, andfurther sends the synchronization signal by using the determinedsubframe and PRB pair. In this way, user equipment receiving thesynchronization signal can identify synchronization signals withdifferent priority parameters according to subframes and PRB pairs thatcarry the synchronization signals, and the user equipment receiving thesynchronization signal can determine a synchronization signal accordingto a priority parameter, thereby improving flexibility of asynchronization signal determining manner. Because the priorityparameter may be at least one of a level and a layer, where the levelmay express a source or precision of the synchronization signal, and thelayer may express a forwarding level of the synchronization signal, theuser equipment receiving the synchronization signal can determine thesynchronization signal for the user equipment itself according to thesource, the precision, or the forwarding level of the synchronizationsignal. This determining manner is more specific, so that the userequipment receiving the synchronization signal can select a moresuitable synchronization signal.

In an embodiment of a synchronization signal carrying method provided inthe present invention, synchronization signals with different priorityparameters may be distinguished by using different time domain resourcesand codeword resources.

The time domain resources herein may be data frames, subframes,timeslots, or orthogonal frequency division multiplexing OFDM symbols,for sending synchronization signals. Distinguishing betweensynchronization signals with different priority parameters according todifferent time domain resources is distinguishing between signals andsynchronization signals with different priority parameters by sendingthe synchronization signals in data frames with different serialnumbers, subframes with different serial numbers, timeslots withdifferent serial numbers, OFDM symbols with different serial numbers, orany combination of the foregoing four resources. The codeword resourcesrefer to codeword sequences used for sending the synchronizationsignals. Distinguishing between priority parameters of signals dependingon time resources and codeword resources is distinguishing between thepriority parameters of the signals by sending the synchronizationsignals by using different codeword sequences in data frames withdifferent serial numbers, subframes with different serial numbers, orOFDM symbols with different serial numbers.

In an example in which priority parameters of synchronization signalsare distinguished by using subframes and codeword sequences, the examplemay be conveniently extended to that priority parameters ofsynchronization signals are distinguished by using data frames andcodewords or by using OFDM symbols and codewords.

It is assumed that 10 subframes are included in a data frame in asystem, and it is assumed that a total of two synchronization sequencesare carried in one data frame, where the two synchronization sequencescarry a same synchronization signal and one synchronization sequence iscarried in the first subframe or carried in the sixth subframe. It isassumed that two different codeword sequences in the system are used tocarry the synchronization sequences: in the first five subframes, asynchronization signal is carried by using a first codeword sequence;and in last five subframes, a synchronization signal is carried by usinga second codeword sequence. Under this condition, the following 17distinguishable combinations of a subframe and a codeword sequence thatcarry a synchronization signal are available: {1(s1),2(s1)},{1(s1),3(s1)}, {1(s1),4(s1)}, {1(s1),5(s1)}, {6(s2,7(s2)},{6(s2),8(s2)}, {6(s2),9(s2)}, {6(s2),10(s2)}, {1(s1),6(s2)},{1(s1),7(s2)}, {1(s1),8(s2)}, {1(s1),9(s2)}, {1(s1),10(s2)},{2(s1),6(s2)}, {3(s1),6(s2)}, {4(s1),6(s2)}, and {5(s1),6(s2)}, where{1(s1),2(s1)} expresses that a synchronization signal is carried byusing the first codeword sequence in the first subframe and carried byusing the first codeword sequence in the second subframe, and{1(s1),6(s2)} expresses that a synchronization signal is carried byusing the first codeword sequence in the first subframe and carried byusing the second codeword sequence in the sixth subframe. 17 differentpriority parameters of synchronization signals can be distinguished byusing the 17 different configurations of a subframe resource and acodeword sequence. In an actual system, a required quantity may beselectively determined from the 17 time configurations to representpriority parameters of the required quantity of synchronization signals.

Further, it is assumed that 2*N subframes are included in a data framein a system, and it is assumed that a total of two synchronizationsequences are carried in one data frame, where the two synchronizationsequences carry a same synchronization signal and one synchronizationsequence is carried in the first subframe or carried in the (N+1)thsubframe. In addition, it is assumed that two different codewordsequences in the system are used to carry the synchronization sequences:in the first N subframes, one synchronization sequence is carried byusing a first codeword sequence; and in the last N subframes, the othersynchronization sequence is carried by using a second codeword sequence.Under this condition, 4*N−3 distinguishable configurations of a subframeand a codeword sequence that carry a synchronization signal areavailable. 4*N−3 different priority parameters of synchronizationsignals can be distinguished by using the 4*N−3 different configurationsof a subframe resource and a codeword sequence. In an actual system, arequired quantity may be determinably determined from the 4*N−3 timeconfigurations and codeword configurations to represent priorityparameters of the required quantity of synchronization signals.

In this embodiment, user equipment determines a priority parameter of asynchronization signal, determines, according to the priority parameter,a subframe and a codeword sequence for carrying the synchronizationsignal, and further sends the synchronization signal by using thedetermined subframe and codeword sequence. In this way, user equipmentreceiving the synchronization signal can identify synchronizationsignals with different priority parameters according to subframes andcodeword sequences that carry the synchronization signals, and the userequipment receiving the synchronization signal can determine asynchronization signal according to a priority parameter, therebyimproving flexibility of a synchronization signal determining manner.Because the priority parameter may be at least one of a level and alayer, where the level may express a source or precision of thesynchronization signal, and the layer may express a forwarding level ofthe synchronization signal, the user equipment receiving thesynchronization signal can determine the synchronization signal for theuser equipment itself according to the source, the precision, or theforwarding level of the synchronization signal. This determining manneris more specific, so that the user equipment receiving thesynchronization signal can select a more suitable synchronizationsignal.

In an embodiment of a synchronization signal carrying method provided inthe present invention, synchronization signals with different priorityparameters may be distinguished by using different frequency resourcesand codeword resources.

The frequency resources may be frequencies occupied for sending thesynchronization signals. A frequency resource may be a PRB pair, or maybe a single subcarrier or a subcarrier group in a PRB pair.Synchronization signals with different priority parameters aredistinguished by using different frequency resources. That is, thesynchronization signals with different priority parameters aredistinguished by sending the synchronization signals on PRB pairs withdifferent serial numbers, subcarriers with different serial numbers, orsubcarriers with different serial numbers in a subcarrier group. Thecodeword resources refer to codeword sequences used for sending thesynchronization signals. Distinguishing between priority parameters ofsignals depending on frequency resources and codeword resources isdistinguishing between the priority parameters of the signals by sendingthe synchronization signals by using different codeword sequences on PRBpairs with different serial numbers, or subcarriers or subcarrier groupswith different serial numbers in different PRB pairs.

In an example in which priority parameters of synchronization signalsare distinguished by using PRB pairs and codeword sequences, the examplemay be conveniently extended to that levels of synchronization signalsare distinguished by using subcarriers in a PRB and codeword sequencesor by using subcarrier groups in a PRB and codeword sequences.

It is assumed that 10 subframes are included in a data frame in asystem, and in addition, it is assumed that a total of onesynchronization sequence is carried in one data frame, where thesynchronization sequence is carried in the first subframe, onesynchronization signal corresponds to one synchronization sequence, andone synchronization sequence is carried by using two codeword sequences.In this case, two different codeword sequences in a system are used tocarry a synchronization sequence. In addition, it is assumed that twodifferent PRB configurations in the system are used to carry asynchronization sequence. Under this condition, the following fourdistinguishable combinations of a PRB configuration and a codewordsequence that carry a synchronization signal are available: {f1(s1)},{f1(s2)}, {f2(s1)}, and {f2(s2)}, where {f1(s1)} expresses that asynchronization signal is carried by using a first codeword sequence ina first PRB configuration in the first subframe. Four different priorityparameters of synchronization signals can be distinguished by using thefour different configurations of a time resource and a frequencyresource. In an actual system, a required quantity may be determinablydetermined from the four time configurations to represent priorityparameters of the required quantity of synchronization signals.

Further, it is assumed that a synchronization signal is carried in thefirst subframe in one data frame. In addition, it is assumed that Mdifferent codeword sequences in a system are used to carry onesynchronization signal, where M is an integer greater than 0. Inaddition, it is assumed that N different PRB configurations in a systemare used to carry a synchronization sequence, where N is an integergreater than 0. Under this condition, M*N distinguishable configurationsof a subframe and a codeword that carry a synchronization signal areavailable. M*N different priority parameters of synchronization signalscan be distinguished by using the M*N different configurations of afrequency resource and a codeword resource. In an actual system, arequired quantity may be selectively determined from the M*N frequencyconfigurations and codeword configurations to represent priorityparameters of the required quantity of synchronization signals.

In this embodiment, user equipment determines a priority parameter of asynchronization signal, determines, according to the priority parameter,a PRB pair and a codeword sequence for carrying the synchronizationsignal, and further sends the synchronization signal by using thedetermined PRB pair and codeword sequence. In this way, user equipmentreceiving the synchronization signal can identify synchronizationsignals with different priority parameters according to PRB pairs andcodeword sequences that carry the synchronization signals, and the userequipment receiving the synchronization signal can determine asynchronization signal according to a priority parameter, therebyimproving flexibility of a synchronization signal determining manner.Because the priority parameter may be at least one of a level and alayer, where the level may express a source or precision of thesynchronization signal, and the layer may express a forwarding level ofthe synchronization signal, the user equipment receiving thesynchronization signal can determine the synchronization signal for theuser equipment itself according to the source, the precision, or theforwarding level of the synchronization signal. This determining manneris more specific, so that the user equipment receiving thesynchronization signal can select a more suitable synchronizationsignal.

In an embodiment of a synchronization signal carrying method provided inthe present invention, synchronization signals with different priorityparameters may be distinguished by using different time resources andcodeword resources.

For specific descriptions about the time resource and the codewordresource herein, reference may be made to related descriptions in theforegoing embodiments, and details are not described herein again.

In an example in which priority parameters of synchronization signalsare distinguished by using subframes and codeword sequences, the examplemay be conveniently extended to that priority parameters ofsynchronization signals are distinguished by using data frames andcodeword sequences or by using OFDM symbols and codeword sequences.

It is assumed that 10 subframes are included in a data frame in asystem, and it is assumed that a total of two synchronization sequencesare carried in one data frame, where the two synchronization sequencescorrespond to one synchronization signal and one synchronizationsequence is carried in the first subframe or carried in the sixthsubframe. In addition, it is assumed that two different codewordsequences in the system are used to separately carry two synchronizationsequences: in the first five subframes, one synchronization sequence iscarried by using a first codeword sequence; and in the last fivesubframes, the other synchronization sequence is carried by using asecond codeword sequence. Under this condition, the following 17distinguishable combinations of a subframe and a codeword sequence thatcarry a synchronization signal are available: {1(s1),2(s1)},{1(s1),3(s1)}, {1(s1),4(s1)}, {1(s1),5(s1)}, {6(s2,7(s2)},{6(s2),8(s2)}, {6(s2),9(s2)}, {6(s2),10(s2)}, {1(s1),6(s2)},{1(s1),7(s2)}, {1(s1),8(s2)}, {1(s1),9(s2)}, {1(s1),10(s2)},{2(s1),6(s2)}, {3(s1),6(s2)}, {4(s1),6(s2)}, and {5(s1),6(s2)}, where{1(s1),2(s1)} expresses that a synchronization signal is carried byusing the first codeword sequence in the first subframe and carried byusing the first codeword sequence in the second subframe, and{1(s1),6(s2)} expresses that a synchronization signal is carried byusing the first codeword sequence in the first subframe and carried byusing the second codeword sequence in the sixth subframe. 17 differentpriority parameters of synchronization signals can be distinguished byusing the 17 different configurations of a time resource and a frequencyresource. In an actual system, a required quantity may be determinablydetermined from the 17 time configurations to represent priorityparameters of the required quantity of synchronization signals.

Further, it is assumed that 2*N subframes are included in a data framein a system, and it is assumed that a total of two synchronizationsequences are carried in one data frame, where one synchronizationsequence is carried in the first subframe or carried in the (N+1)thsubframe. In addition, it is assumed that two different codewordsequences in the system are used to carry the synchronization sequences:in the first N subframes, one synchronization sequence is carried byusing a first codeword sequence; and in the last N subframes, the othersynchronization sequence is carried by using a second codeword sequence.Under this condition, 4*N−3 distinguishable configurations of a subframeand a codeword that carry a synchronization signal are available. 4*N−3different priority parameters of synchronization signals can bedistinguished by using the 4*N−3 different configurations of a timeresource and a codeword resource. In an actual system, a requiredquantity may be selectively determined from the 4*N−3 timeconfigurations and codeword configurations to represent priorityparameters of the required quantity of synchronization signals.

In this embodiment, user equipment determines a priority parameter of asynchronization signal, determines, according to the priority parameter,a subframe and a codeword sequence for carrying the synchronizationsignal, and further sends the synchronization signal by using thedetermined subframe and codeword sequence. In this way, user equipmentreceiving the synchronization signal can identify synchronizationsignals with different priority parameters according to subframes andcodeword sequences that carry the synchronization signals, and the userequipment receiving the synchronization signal can determine asynchronization signal according to a priority parameter, therebyimproving flexibility of a synchronization signal determining manner.Because the priority parameter may be at least one of a level and alayer, where the level may express a source or precision of thesynchronization signal, and the layer may express a forwarding level ofthe synchronization signal, the user equipment receiving thesynchronization signal can determine the synchronization signal for theuser equipment itself according to the source, the precision, or theforwarding level of the synchronization signal. This determining manneris more specific, so that the user equipment receiving thesynchronization signal can select a more suitable synchronizationsignal.

In an embodiment of a synchronization signal carrying method provided inthe present invention, synchronization signals with different priorityparameters may be distinguished by using different frequency resourcesand codeword resources.

For specific descriptions about the frequency resource and the codewordresource herein, reference may be made to related descriptions in theforegoing embodiments, and details are not described herein again.

In an example in which priority parameters of synchronization signalsare distinguished by using PRB pairs and codeword sequences, the examplemay be conveniently extended to that priority parameters ofsynchronization signals are distinguished by using subcarriers in a PRBpair and codeword sequences or by using subcarrier groups in a PRB pairand codeword sequences.

It is assumed that 10 subframes are included in a data frame in asystem, and it is assumed that a total of one synchronization signal iscarried in one data frame, where the synchronization signal is carriedin the first subframe, one synchronization signal corresponds to onesynchronization sequence, and one synchronization sequence is carried byusing two codeword sequences. In this case, two different codewordsequences in the system are used to carry one synchronization signal. Inaddition, it is assumed that two different PRB configurations in thesystem are used to carry a synchronization signal. Under this condition,the following four distinguishable combinations of a PRB configurationand a codeword sequence that carry a synchronization signal areavailable: {f1(s1)}, {f1(s2)}, {f2(s1)}, and {f2(s2)}, where {f1(s1)}expresses that a synchronization signal is carried by using a firstcodeword sequence in a first PRB configuration in the first subframe.Four different priority parameters of synchronization signals can bedistinguished by using the four different configurations of a timeresource and a frequency resource. In an actual system, a requiredquantity may be determinably determined from the four timeconfigurations to represent priority parameters of the required quantityof synchronization signals.

Further, by the same analogy, it is assumed that a synchronizationsignal is carried in the first subframe in one data frame. In addition,it is assumed that M different codeword sequences in a system are usedto carry one synchronization signal. In addition, it is assumed that Ndifferent PRB configurations in the system are used to carry asynchronization signal. Under this condition, M*N distinguishableconfigurations of a subframe and a codeword that carry a synchronizationsignal are available. M*N different priority parameters ofsynchronization signals can be distinguished by using the M*N differentconfigurations of a frequency resource and a codeword resource. In anactual system, a required quantity may be selectively determined fromthe M*N frequency configurations and codeword configurations torepresent priority parameters of the required quantity ofsynchronization signals.

In this embodiment, user equipment determines a priority parameter of asynchronization signal, determines, according to the priority parameter,a PRB pair and a codeword sequence for carrying the synchronizationsignal, and further sends the synchronization signal by using thedetermined PRB pair and codeword sequence. In this way, user equipmentreceiving the synchronization signal can identify synchronizationsignals with different priority parameters according to PRB pairs andcodeword sequences that carry the synchronization signals, and the userequipment receiving the synchronization signal can determine asynchronization signal according to a priority parameter, therebyimproving flexibility of a synchronization signal determining manner.Because the priority parameter may be at least one of a level and alayer, where the level may express a source or precision of thesynchronization signal, and the layer may express a forwarding level ofthe synchronization signal, the user equipment receiving thesynchronization signal can determine the synchronization signal for theuser equipment itself according to the source, the precision, or theforwarding level of the synchronization signal. This determining manneris more specific, so that the user equipment receiving thesynchronization signal can select a more suitable synchronizationsignal.

In an embodiment of a synchronization signal carrying method provided inthe present invention, synchronization signals with different priorityparameters may be distinguished by using different time resources,frequency resources, and codeword resources.

For specific descriptions about the time resource, the frequencyresource, and the codeword resource herein, reference may be made torelated descriptions in the foregoing embodiments.

In an example in which priority parameters of synchronization signalsare distinguished by using configurations of a subframe, a codewordsequence, and a PRB, the example may be conveniently extended to thatpriority parameters of synchronization signals are distinguished byusing another manner.

It is assumed that 10 subframes are included in a data frame in asystem, and it is assumed that a total of two synchronization sequencesare carried in one data frame, where the two synchronization sequencescorrespond to one synchronization signal, and one synchronizationsequence is carried in the first subframe or carried in the sixthsubframe. In addition, it is assumed that two different codewordsequences in the system are used to carry one synchronization signal. Inaddition, it is assumed that two different PRB configurations in thesystem are used to carry one synchronization signal: in the first fivesubframes, one synchronization sequence of the synchronization signal iscarried by using a first PRB configuration; and in the last fivesubframes, the other synchronization sequence of the synchronizationsignal is carried by using a second PRB configuration. Under thiscondition, 17*4 distinguishable combinations of configurations of asubframe, a codeword sequence, and a PRB that carry a synchronizationsignal are available. 17 combinations that use merely codeword 1 areshown in the following table:

TABLE 1 Table of combinations of different subframe configurationsConfiguration Subframe Subframe Subframe Subframe No. Subframe 1Subframe 2 Subframe 3 Subframe 4 Subframe 5 Subframe 6 7 8 9 10 1 (f1,s1) (f1, s1) 2 (f1, s1) (f1, s1) 3 (f1, s1) (f1, s1) 4 (f1, s1) (f1, s1)5 (f2, s1) (f2, s1) 6 (f2, s1) (f2, s1) 7 (f2, s1) (f2, s1) 8 (f2, s1)(f2, s1) 9 (f1, s1) (f2, s1) 10 (f1, s1) (f2, s1) 11 (f1, s1) (f2, s1)12 (f1, s1) (f2, s1) 13 (f1, s1) (f2, s1) 14 (f1, s1) (f2, s1) 15 (f1,s1) (f2, s1) 16 (f1, s1) (f2, s1) 17 (f1, s1) (f2, s1)

In configuration 1, a synchronization signal is sent by using a firstcodeword sequence in a first PRB configuration in the first frame andsent by using the first codeword sequence in the first PRB configurationin the second frame; and in configuration 9, a synchronization signal issent by using the first codeword sequence in the first PRB configurationin the first frame and sent by using the first codeword sequence in asecond PRB configuration in the sixth frame.

The foregoing table shows 17 configurations that use merely codeword 1.For two adjacent synchronization sequences, {Codeword 1, Codeword 2},{Codeword 2, Codeword 1}, and {Codeword 2, Codeword 2} correspond to 17configurations separately. Therefore, there are 17*4 configurations intotal.

17*4 different priority parameters of synchronization signals can bedistinguished by using the 17*4 different configurations of a timeresource, a frequency resource, and a codeword resource. In an actualsystem, a required quantity may be determinably determined from the 17*4time configurations to represent priority parameters of the requiredquantity of synchronization signals.

Further, it is assumed that 2*N subframes are included in a data framein a system, where N is an integer greater than 0, and it is assumedthat a total of two synchronization sequences are carried in one dataframe, where the two synchronization sequences correspond to onesynchronization signal and one synchronization sequence is carried inthe first subframe or carried in the (N+1)th subframe. In addition, itis assumed that two different codeword sequences in the system are usedto carry a synchronization signal. In addition, it is assumed that twodifferent PRB configurations in the system are used to carry asynchronization signal: in the first N subframes, a synchronizationsignal is carried by using a first PRB configuration; and in the last Nsubframes, a synchronization signal is carried by using a second PRBconfiguration. Under this condition, 4*(4*N−3) distinguishablecombinations of configurations of a subframe, a codeword sequence, and aPRB that carry a synchronization signal are available. 4*(4*N−3)different priority parameters of synchronization signals can bedistinguished by using the 4*(4*N−3) different configurations of a timeresource and a codeword resource. In an actual system, a requiredquantity may be determinably determined from the 4*(4*N−3) timeconfigurations, codeword configurations, and frequency configurations torepresent priority parameters of the required quantity ofsynchronization signals.

In this embodiment, user equipment determines a priority parameter of asynchronization signal, determines, according to the priority parameter,a subframe, a PRB pair, and a codeword sequence for carrying thesynchronization signal, and further sends the synchronization signal byusing the determined subframe, PRB pair, and codeword sequence. In thisway, user equipment receiving the synchronization signal can identifysynchronization signals with different priority parameters according tosubframes, PRB pairs, and codeword sequences that carry thesynchronization signals, and the user equipment receiving thesynchronization signal can determine a synchronization signal accordingto a priority parameter, thereby improving flexibility of asynchronization signal determining manner. Because the priorityparameter may be at least one of a level and a layer, where the levelmay express a source or precision of the synchronization signal, and thelayer may express a forwarding level of the synchronization signal, theuser equipment receiving the synchronization signal can determine thesynchronization signal for the user equipment itself according to thesource, the precision, or the forwarding level of the synchronizationsignal. This determining manner is more specific, so that the userequipment receiving the synchronization signal can select a moresuitable synchronization signal.

In an embodiment of a synchronization signal carrying method provided inthe present invention, synchronization signals with different priorityparameters may be distinguished by using different time resources andcodeword resources.

It is assumed that 10 subframes are included in a data frame in asystem, and it is assumed that a total of two synchronization sequencesare carried in one data frame, where the two synchronization sequencescorrespond to one synchronization signal and one synchronizationsequence is carried in the first subframe or carried in the sixthsubframe. In addition, it is assumed that two different codewordsequences in the system are used to carry a synchronization signal: inthe first five subframes, one synchronization sequence of thesynchronization signal is carried by using a first codeword sequence;and in the last five subframes, the other synchronization sequence ofthe synchronization signal is carried by using a second codewordsequence. Under this condition, the following 17 distinguishablecombinations of a subframe and a codeword sequence that carry asynchronization signal are available: {1(s1),2(s1)}, {1(s1),3(s1)},{1(s1),4(s1)}, {1(s1),5(s1)}, {6(s2,7(s2)}, {6(s2),8(s2)},{6(s2),9(s2)}, {6(s2),10(s2)}, {1(s1),6(s2)}, {1(s1),7(s2)},{1(s1),8(s2)}, {1(s1),9(s2)}, {1(s1),10(s2)}, {2(s1),6(s2)},{3(s1),6(s2)}, {4(s1),6(s2)}, and {5(s1),6(s2)}, where {1(s1),2(s1)}expresses that a synchronization signal is carried by using codeword 1in the first subframe and carried by using the first codeword sequencein the second subframe, and {1(s1),6(s2)} expresses that asynchronization signal is carried by using the first codeword sequencein the first subframe and carried by using the second codeword sequencein the sixth subframe.

A table may be used to display all configurations more clearly, as shownin the following table:

TABLE 2 Table of different combinations of a time and a codewordConfiguration Subframe Subframe Subframe Subframe Subframe SubframeSubframe Subframe {Level, No. Subframe 1 Subframe 2 3 4 5 6 7 8 9 10Layer} 1 S1 S1 {1, 1} 2 S1 S1 {1, 2} 3 S1 S1 {1, 3} 4 S1 S1 {1, 4} 5 S2S2 {2, 1} 6 S2 S2 {2, 2} 7 S2 S2 {2, 3} 8 S2 S2 {2, 4} 9 S1 S2 {3, 1} 10S1 S2 {3, 2} 11 S1 S2 {3, 3} 12 S1 S2 {3, 4} 13 S1 S2 {3, 5} 14 S1 S2{3, 6} 15 S1 S2 {3, 7} 16 S1 S2 {3, 8} 17 S1 S2 {3, 9}

In configuration 1, a synchronization signal is sent by using the firstcodeword sequence in the first frame and sent by using the firstcodeword sequence in the second frame; and in configuration 9, asynchronization signal is sent by using the first codeword sequence inthe first frame and sent by using the second codeword sequence in thesixth frame.

17 synchronization signals with different priority parameters can bedistinguished by using the 17 different configurations of a timeresource and a frequency resource. In an actual system, a requiredquantity may be selectively determined from the 17 time configurationsto represent priority parameters of the required quantity ofsynchronization signals.

Further, it is assumed that 2*N subframes are included in a data framein a system, where N is an integer greater than 0, and it is assumedthat a total of two synchronization sequences are carried in one dataframe, where the two synchronization sequences correspond to onesynchronization signal, and one synchronization sequence is carried inthe first subframe or carried in the (N+1)th subframe. In addition, itis assumed that two different codeword sequences in the system are usedto carry a synchronization signal: in the first N subframes, onecodeword sequence of the synchronization signal is carried by using afirst codeword sequence; and in the last N subframes, another codewordsequence of the synchronization signal is carried by using a secondcodeword sequence. Under this condition, 4*N−3 distinguishableconfigurations of a subframe and a codeword that carry a synchronizationsignal are available. 4*N−3 different priority parameters ofsynchronization signals can be distinguished by using the 4*N−3different configurations of a time resource and a codeword resource. Inan actual system, a required quantity may be determinably determinedfrom the 4*N−3 time configurations and codeword configurations torepresent priority parameters of the required quantity ofsynchronization signals.

In this embodiment, user equipment determines a priority parameter of asynchronization signal, determines, according to the priority parameter,a subframe and a codeword sequence for carrying the synchronizationsignal, and further sends the synchronization signal by using thedetermined subframe and codeword sequence. In this way, user equipmentreceiving the synchronization signal can identify synchronizationsignals with different priority parameters according to subframes andcodeword sequences that carry the synchronization signals, and the userequipment receiving the synchronization signal can determine asynchronization signal according to a priority parameter, therebyimproving flexibility of a synchronization signal determining manner.Because the priority parameter may be at least one of a level and alayer, where the level may express a source or precision of thesynchronization signal, and the layer may express a forwarding level ofthe synchronization signal, the user equipment receiving thesynchronization signal can determine the synchronization signal for theuser equipment itself according to the source, the precision, or theforwarding level of the synchronization signal. This determining manneris more specific, so that the user equipment receiving thesynchronization signal can select a more suitable synchronizationsignal.

FIG. 7 is a schematic structural diagram of an embodiment of userequipment according to the present invention. The user equipmentincludes:

a parameter determining module 11, configured to determine a priorityparameter of a synchronization signal;

a resource determining module 12, configured to determine, according tothe priority parameter, a resource for carrying the synchronizationsignal, where a configuration of the resource indicates the priorityparameter; and

a sending module 13, configured to send the synchronization signal tosecond user equipment by using the resource, so that the second userequipment determines a synchronization signal for the second userequipment.

Optionally, the resource determining module 12 may be specificallyconfigured to determine different resources to carry synchronizationsignals with different priority parameters.

Optionally, the priority parameter may include at least one of a leveland a layer, where the level is used to identify a source of thesynchronization signal or used to identify precision of thesynchronization signal; and the layer is used to identify a forwardinglevel of the synchronization signal; and the synchronization signalswith different priority parameters are specifically synchronizationsignals that differ in at least one of the level and the layer.

Optionally, the source of the synchronization signal may include: aglobal satellite positioning system number, a network device, or firstuser equipment.

Optionally, the resource may include: a time domain resource, afrequency domain resource, and a codeword resource; and the differentresources are specifically resources that differ in at least one of atime domain, a frequency domain, and a codeword.

Optionally, that time domain resources carrying the synchronizationsignals are different includes at least one of the following: serialnumbers carrying the synchronization signals are different; serialnumbers of timeslots carrying the synchronization signals are different;serial numbers of subframes carrying the synchronization signals aredifferent; and serial numbers of OFDM symbols carrying thesynchronization signals are different.

Optionally, that frequency domain resources carrying the synchronizationsignals are different includes at least one of the following: serialnumbers of PRBs carrying the synchronization signals are different;serial numbers of subcarriers carrying the synchronization signals aredifferent; and serial numbers of subcarriers in a subcarrier groupcarrying the synchronization signals are different.

Optionally, the resources that differ in a codeword may be specificallyresources that differ in a codeword sequence.

Optionally, the codeword sequence may be a sequence with a length of 63bits:

${d_{u}(n)} = ^{{- j}\frac{\pi \; {{un}{({n + 1})}}}{63}}$n = 0, 1, …  , 30, 31, 32, …  , 61, 62,

where

a value of u is 25, 29, or 34, and three different codeword sequencesare generated separately.

The user equipment for carrying a synchronization signal according tothis embodiment of the present invention corresponds to the methodembodiments provided in FIG. 1 and FIG. 3 to FIG. 6 in the presentinvention and is an execution body of the method embodiments. Therefore,for a specific process of executing the synchronization signal carryingmethod by the user equipment, reference may be made to the methodembodiments, and details are not described herein again.

The user equipment according to this embodiment determines a priorityparameter of a synchronization signal, determines, according to thepriority parameter, a resource for carrying the synchronization signal,and further sends the synchronization signal by using the determinedresource. In this way, user equipment receiving the synchronizationsignal can identify synchronization signals with different priorityparameters according to resources carrying the synchronization signals,and the user equipment receiving the synchronization signal candetermine a synchronization signal according to a priority parameter,thereby improving flexibility of a synchronization signal determiningmanner. Because the priority parameter may be at least one of a leveland a layer, where the level may express a source or precision of thesynchronization signal, and the layer may express a forwarding level ofthe synchronization signal, the user equipment receiving thesynchronization signal can determine the synchronization signal for theuser equipment itself according to the source, the precision, or theforwarding level of the synchronization signal. This determining manneris more specific, so that the user equipment receiving thesynchronization signal can select a more suitable synchronizationsignal.

FIG. 8 is a schematic structural diagram of still another embodiment ofuser equipment according to the present invention. As shown in FIG. 8,the user equipment includes:

a receiving module 21, configured to receive a synchronization signalsent by first user equipment; and

a determining module 22, configured to determine a priority parameteraccording to a resource carrying the synchronization signal and acorrespondence between the resource and the priority parameter of thesynchronization signal; and

the determining module 22 is further configured to determine asynchronization signal for second user equipment according to thepriority parameter.

Optionally, synchronization signals with different priority parametersmay be carried by using different resources.

Optionally, the priority parameter may include at least one of a leveland a layer, where the level is used to identify a source of thesynchronization signal or used to identify precision of thesynchronization signal; and the layer is used to identify a forwardinglevel of the synchronization signal; and the synchronization signalswith different priority parameters are specifically synchronizationsignals that differ in at least one of the level and the layer.

Optionally, the source of the synchronization signal may include: aglobal satellite positioning system, a network device, or the first userequipment.

Optionally, the resource may include: a time domain resource, afrequency domain resource, and a codeword resource; and the differentresources are specifically resources that differ in at least one of atime domain, a frequency domain, and a codeword.

Optionally, that time domain resources carrying the synchronizationsignals are different includes at least one of the following: serialnumbers of data frames carrying the synchronization signals aredifferent; serial numbers of timeslots carrying the synchronizationsignals are different; serial numbers of subframes carrying thesynchronization signals are different; and serial numbers of OFDMsymbols carrying the synchronization signals are different.

Optionally, that frequency domain resources carrying the synchronizationsignals are different includes at least one of the following: serialnumbers of PRBs carrying the synchronization signals are different;serial numbers of subcarriers carrying the synchronization signals aredifferent; and serial numbers of subcarriers in a subcarrier groupcarrying the synchronization signals are different.

Optionally, the resources that differ in a codeword may be specificallyresources that differ in a codeword sequence.

Optionally, the codeword sequence may be a sequence with a length of 63bits:

${d_{u}(n)} = ^{{- j}\frac{\pi \; {{un}{({n + 1})}}}{63}}$n = 0, 1, …  , 30, 31, 32, …  , 61, 62,

where

a value of u is 25, 29, or 34.

The user equipment for carrying a synchronization signal according tothis embodiment of the present invention corresponds to the methodembodiments provided in FIG. 2 to FIG. 6 in the present invention and isan execution body of the method embodiments. Therefore, for a specificprocess of executing the synchronization signal carrying method by theuser equipment, reference may be made to the method embodiments, anddetails are not described herein again.

The user equipment according to this embodiment of the present inventiondetermines, after receiving a synchronization signal sent by anotheruser equipment, a priority parameter of the synchronization signalaccording to a resource carrying the synchronization signal and acorrespondence between the resource and the priority parameter of thesynchronization signal, and determines a synchronization signal for theuser equipment itself according to the priority parameter. A determiningmanner is more flexible. Because the priority parameter may be at leastone of a level and a layer, where the level may express a source orprecision of the synchronization signal, and the layer may express aforwarding level of the synchronization signal, the user equipmentreceiving the synchronization signal can determine the synchronizationsignal for the user equipment itself according to the source, theprecision, or the forwarding level of the synchronization signal. Thisdetermining manner is more specific, so that the user equipmentreceiving the synchronization signal can select a more suitablesynchronization signal.

FIG. 9 is a schematic structural diagram of still another embodiment ofuser equipment according to the present invention. The user equipmentincludes: a transceiver 31 and a processor 32, where

the processor 31 is configured to determine a priority parameter of asynchronization signal and determine, according to the priorityparameter, a resource for carrying the synchronization signal, where aconfiguration of the resource indicates the priority parameter; and

the transceiver 32 is configured to send the synchronization signal toanother user equipment by using the resource, so that the another userequipment determines a synchronization signal for the another userequipment.

Optionally, the processor 31 may be specifically configured to determinedifferent resources to carry synchronization signals with differentpriority parameters.

Optionally, the priority parameter may include at least one of a leveland a layer, where the level is used to identify a source of thesynchronization signal or used to identify precision of thesynchronization signal; and the layer is used to identify a forwardinglevel of the synchronization signal; and the synchronization signalswith different priority parameters are specifically synchronizationsignals that differ in at least one of the level and the layer.

Optionally, the source of the synchronization signal includes: a globalsatellite positioning system, a network device, or the user equipment.

Optionally, the resource includes: a time domain resource, a frequencydomain resource, and a codeword resource; and the different resourcesare specifically resources that differ in at least one of a time domain,a frequency domain, and a codeword.

Optionally, that time domain resources carrying the synchronizationsignals are different includes at least one of the following: serialnumbers of data frames carrying the synchronization signals aredifferent; serial numbers of timeslots carrying the synchronizationsignals are different; serial numbers of subframes carrying thesynchronization signals are different; and serial numbers of OFDMsymbols carrying the synchronization signals are different.

Optionally, that frequency domain resources carrying the synchronizationsignals are different includes at least one of the following: serialnumbers of PRBs carrying the synchronization signals are different;serial numbers of subcarriers carrying the synchronization signals aredifferent; and serial numbers of subcarriers in a subcarrier groupcarrying the synchronization signals are different.

Optionally, the resources that differ in a codeword are specificallyresources that differ in a codeword sequence.

Optionally, the codeword sequence is a sequence with a length of 63bits:

${d_{u}(n)} = ^{{- j}\frac{\pi \; {{un}{({n + 1})}}}{63}}$n = 0, 1, …  , 30, 31, 32, …  , 61, 62,

where

a value of u is 25, 29, or 34, and three different codeword sequencesare generated separately.

The user equipment for carrying a synchronization signal according tothis embodiment of the present invention corresponds to the methodembodiments provided in FIG. 1 and FIG. 3 to FIG. 6 in the presentinvention and is an execution body of the method embodiments. Therefore,for a specific process of executing the synchronization signal carryingmethod by the user equipment, reference may be made to the methodembodiments, and details are not described herein again.

The user equipment according to this embodiment determines a priorityparameter of a synchronization signal, determines, according to thepriority parameter, a resource for carrying the synchronization signal,and further sends the synchronization signal by using the determinedresource. In this way, user equipment receiving the synchronizationsignal can identify synchronization signals with different priorityparameters according to resources carrying the synchronization signals,and the user equipment receiving the synchronization signal candetermine a synchronization signal according to a priority parameter,thereby improving flexibility of a synchronization signal determiningmanner. Because the priority parameter may be at least one of a leveland a layer, where the level may express a source or precision of thesynchronization signal, and the layer may express a forwarding level ofthe synchronization signal, the user equipment receiving thesynchronization signal can determine the synchronization signal for theuser equipment itself according to the source, the precision, or theforwarding level of the synchronization signal. This determining manneris more specific, so that the user equipment receiving thesynchronization signal can select a more suitable synchronizationsignal.

FIG. 10 is a schematic structural diagram of still another embodiment ofuser equipment according to the present invention. The user equipmentincludes: a transceiver 41 and a processor 42, where

the transceiver 41 is configured to receive a synchronization signalsent by another user equipment; and

the processor 42 is configured to determine a priority parameteraccording to a resource carrying the synchronization signal and acorrespondence between the resource and the priority parameter of thesynchronization signal, and determine a synchronization signal for theuser equipment according to the priority parameter.

Optionally, synchronization signals with different priority parametersare carried by using different resources.

Optionally, the priority parameter includes at least one of a level anda layer, where the level is used to identify a source of thesynchronization signal or used to identify precision of thesynchronization signal; and the layer is used to identify a forwardinglevel of the synchronization signal; and the synchronization signalswith different priority parameters are specifically synchronizationsignals that differ in at least one of the level and the layer.

Optionally, the source of the synchronization signal includes: a globalsatellite positioning system, a network device, or the first userequipment.

Optionally, the resource includes: a time domain resource, a frequencydomain resource, and a codeword resource; and the different resourcesare specifically resources that differ in at least one of a time domain,a frequency domain, and a codeword.

Optionally, that time domain resources carrying the synchronizationsignals are different includes at least one of the following: serialnumbers of data frames are different; serial numbers of timeslotscarrying the synchronization signals are different; serial numbers ofsubframes carrying the synchronization signals are different; and serialnumbers of OFDM symbols carrying the synchronization signals aredifferent.

Optionally, that frequency domain resources carrying the synchronizationsignals are different includes at least one of the following: serialnumbers of PRBs carrying the synchronization signals are different;serial numbers of subcarriers carrying the synchronization signals aredifferent; and serial numbers of subcarriers in a subcarrier groupcarrying the synchronization signals are different.

Optionally, the resources that differ in a codeword are specificallyresources that differ in a codeword sequence.

Optionally, the codeword sequence is a sequence with a length of 63bits:

${d_{u}(n)} = ^{{- j}\frac{\pi \; {{un}{({n + 1})}}}{63}}$n = 0, 1, …  , 30, 31, 32, …  , 61, 62,

where

a value of u is 25, 29, or 34.

The user equipment for carrying a synchronization signal according tothis embodiment of the present invention corresponds to the methodembodiments provided in FIG. 2 to FIG. 6 in the present invention and isan execution body of the method embodiments. Therefore, for a specificprocess of executing the synchronization signal carrying method by theuser equipment, reference may be made to the method embodiments, anddetails are not described herein again.

The user equipment according to this embodiment of the present inventiondetermines, after receiving a synchronization signal sent by anotheruser equipment, a priority parameter of the synchronization signalaccording to a resource carrying the synchronization signal and acorrespondence between the resource and the priority parameter of thesynchronization signal, and determines a synchronization signal for theuser equipment itself according to the priority parameter. A determiningmanner is more flexible. Because the priority parameter may be at leastone of a level and a layer, where the level may express a source orprecision of the synchronization signal, and the layer may express aforwarding level of the synchronization signal, the user equipmentreceiving the synchronization signal can determine the synchronizationsignal for the user equipment itself according to the source, theprecision, or the forwarding level of the synchronization signal. Thisdetermining manner is more specific, so that the user equipmentreceiving the synchronization signal can select a more suitablesynchronization signal.

Persons of ordinary skill in the art may understand that all or some ofthe steps of the method embodiments may be implemented by a programinstructing relevant hardware. The program may be stored in acomputer-readable storage medium. When the program runs, the steps ofthe method embodiments are performed. The foregoing storage mediumincludes: any medium that can store program code, such as a ROM, a RAM,a magnetic disk, or an optical disc.

Finally, it should be noted that the foregoing embodiments are merelyintended for describing the technical solutions of the presentinvention, but not for limiting the present invention. Although thepresent invention is described in detail with reference to the foregoingembodiments, persons of ordinary skill in the art should understand thatthey may still make modifications to the technical solutions describedin the foregoing embodiments or make equivalent replacements to some orall technical features thereof, without departing from the scope of thetechnical solutions of the embodiments of the present invention.

1-66. (canceled)
 67. A synchronization signal carrying method,comprising: determining, by first user equipment, a priority parameterof a synchronization signal; determining, by the first user equipmentaccording to the priority parameter, a resource for carrying thesynchronization signal, wherein a configuration of the resourceindicates the priority parameter; and sending, by the first userequipment, the synchronization signal to second user equipment by usingthe resource, so that the second user equipment determines asynchronization signal for the second user equipment.
 68. The methodaccording to claim 67, wherein the determining, by the first userequipment according to the priority parameter, a resource for carryingthe synchronization signal specifically comprises: determining, by thefirst user equipment, different resources to carry synchronizationsignals with different priority parameters.
 69. The method according toclaim 68, wherein the priority parameter comprises at least one of alevel and a layer, wherein the level is used to identify a source of thesynchronization signal or used to identify precision of thesynchronization signal; and the layer is used to identify a forwardinglevel of the synchronization signal; and the synchronization signalswith different priority parameters are specifically synchronizationsignals that differ in at least one of the level and the layer.
 70. Themethod according to claim 69, wherein the source comprises: a globalnavigation satellite system, a network device, or the first userequipment.
 71. The method according to claim 70, wherein the resourcecomprises: a time domain resource, a frequency domain resource, and acodeword resource; and the different resources are specificallyresources that differ in at least one of a time domain, a frequencydomain, and a codeword.
 72. The method according to claim 71, wherein:that time domain resources carrying the synchronization signals differin at least one of the following aspects: serial numbers of data framescarrying the synchronization signals; serial numbers of timeslotscarrying the synchronization signals; serial numbers of subframescarrying the synchronization signals; and serial numbers of orthogonalfrequency division multiplexing (OFDM) symbols carrying thesynchronization signals.
 73. The method according to claim 71, whereinthat frequency domain resources carrying the synchronization signalsdiffer in at least one of the following aspects: serial numbers ofphysical resource blocks (PRBs) carrying the synchronization signals;serial numbers of subcarriers carrying the synchronization signals; andserial numbers of subcarriers in a subcarrier group carrying thesynchronization signals.
 74. The method according to claim 71, whereinthe resources that differ in a codeword are specifically resources thatdiffer in a codeword sequence.
 75. The method according to claim 74,wherein the codeword sequence is a sequence with a length of 63 bits:${d_{u}(n)} = ^{{- j}\frac{\pi \; {{un}{({n + 1})}}}{63}}$n = 0, 1, …  , 30, 31, 32, …  , 61, 62, wherein a value of u is 25,29, or 34, and three different codeword sequences are generatedseparately.
 76. User equipment, comprising: a transceiver and aprocessor, wherein the processor is configured to determine a priorityparameter of a synchronization signal and determine, according to thepriority parameter, a resource for carrying the synchronization signal,wherein a configuration of the resource indicates the priorityparameter; and the transceiver is configured to send the synchronizationsignal to another user equipment by using the resource, so that theanother user equipment determines a synchronization signal for theanother user equipment.
 77. The user equipment according to claim 76,wherein the processor is specifically configured to determine differentresources to carry synchronization signals with different priorityparameters.
 78. The user equipment according to claim 77, wherein thepriority parameter comprises at least one of a level and a layer,wherein the level is used to identify a source of the synchronizationsignal or used to identify precision of the synchronization signal; andthe layer is used to identify a forwarding level of the synchronizationsignal; and the synchronization signals with different priorityparameters are specifically synchronization signals that differ in atleast one of the level and the layer.
 79. The user equipment accordingto claim 78, wherein the source comprises: a global navigation satellitesystem, a network device, or the user equipment.
 80. The user equipmentaccording to claim 79, wherein the resource comprises: a time domainresource, a frequency domain resource, and a codeword resource; and thedifferent resources are specifically resources that differ in at leastone of a time domain, a frequency domain, and a codeword.
 81. The userequipment according to claim 80, wherein that time domain resourcescarrying the synchronization signals differ in at least one of thefollowing aspects: serial numbers of data frames carrying thesynchronization signals; serial numbers of timeslots carrying thesynchronization signals; serial numbers of subframes carrying thesynchronization signals; and serial numbers of orthogonal frequencydivision multiplexing (OFDM) symbols carrying the synchronizationsignals.
 82. The user equipment according to claim 80, wherein thatfrequency domain resources carrying the synchronization signals differin at least one of the following aspects: serial numbers of physicalresource blocks (PRBs) carrying the synchronization signals; serialnumbers of subcarriers carrying the synchronization signals; and serialnumbers of subcarriers in a subcarrier group carrying thesynchronization signals.
 83. The user equipment according to claim 82,wherein the resources that differ in a codeword are specificallyresources that differ in a codeword sequence.
 84. A synchronizationsignal carrying method, comprising: receiving, by second user equipment,a synchronization signal sent by first user equipment; determining, bythe second user equipment, a priority parameter according to a resourcecarrying the synchronization signal and a correspondence between theresource and the priority parameter of the synchronization signal; anddetermining, by the second user equipment, a synchronization signal forthe second user equipment according to the priority parameter.
 85. Themethod according to claim 84, wherein synchronization signals withdifferent priority parameters are carried by using different resources.86. The method according to claim 85, wherein the priority parametercomprises at least one of a level and a layer, wherein the level is usedto identify a source of the synchronization signal or used to identifyprecision of the synchronization signal; and the layer is used toidentify a forwarding level of the synchronization signal; and thesynchronization signals with different priority parameters arespecifically synchronization signals that differ in at least one of thelevel and the layer.